S1-01: The journey from student to SpaceX engineer: Juan Vivas
In this episode, we join Eric Cross as he talks to supply chain engineer Juan Vivas of SpaceX about his experiences growing up as a Latino in STEM. Juan shares his story of moving to the United States to study engineering and becoming successful in his career as a scientist. Juan openly discusses the experiences that made a difference in his life and the teachers that inspired him along the way. He also shares his experience as an engineer in different fields, as well as what it’s like to work in the supply chain during COVID.
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Juan Vivas (00:00):
But to me, based on my experience so far, I think the best way to put it: An engineer is a technical problem-solver.
Eric Cross (00:28):
Welcome to Science Connections. I’m your host, Eric Cross. My guest today is Juan Vivas. Juan is a supply chain engineer for SpaceX. His career in STEM has pivoted from chemical engineering to working on foods like Cinnamon Toast Crunch to his current role at SpaceX, where he’s responsible for his work on Starlink, a technology that uses low-orbit satellites to provide internet access across the world. In this episode, Juan shares his story of how he became an engineer and how a thoughtful teacher used robotics to inspire him. I hope you enjoy this great conversation with Juan Vivas. Juan, thanks for being here.
Juan Vivas (01:14):
Yeah, yeah, of course! Super-excited to be here.
Eric Cross (01:19):
Hey, and starting off, I kind of like to ask your origin story. We were talking earlier about Marvel, and your journey of one working for…what I consider the closest thing that we have to SHIELD in the Marvel stories is SpaceX. Like with my own students, we talk about SpaceX like it’s a fictional thing, and we watch the rocket launches together and we watch the recovery and it’s so cool.
Juan Vivas (01:45):
Yeah.
Eric Cross (01:46):
And so when I knew that we were gonna be able to talk to you, I was excited. Like, I felt like I was a kid.
Juan Vivas (01:51):
<Laugh>
Eric Cross (01:51):
So I’d love to hear your origin story of you ultimately landing at SpaceX. And begin wherever kind of seems most natural to you.
Juan Vivas (01:59):
Yeah, yeah, of course. You know, I wasn’t one of those kids at from a young age I said “Oh, I’m gonna be an engineer.” Right? “I want to go and build all these things.” Where I grew up, and the social circle that I had, a lot of people were like doctors or lawyers. Just figured, you know, I’ll go to med school and go down the same path that 90% of like everyone else was gonna take. But in high school, I actually got into robotics. And, kind of like I mentioned, I wanted to do med school, that is what I figured I would end up doing. And then I got into robotics in high school. And I think that was what really kind of like changed my perspective of what I wanted to do, because basically these competitions were just—it was full-on driven by students. So we designed, programmed, and manufactured, like, the entire robot itself. And so through that I ended up doing a summer engineering program at the University of Maryland, the summer before going into my senior year in high school. And there we worked on a competition with underwater robots. And so we spent the entire summer, kind of similar scenario, designing a robot, manufacturing it, programming it. And then in the end it was like a competition in the buoyancy tank with different teams. And, you know, I think one thing that was really neat about that experience is that I got to hear Dr. John C. Mathers, who is a Nobel Prize physicist, speak to us in a room with, like, only 10 high school students. And just hearing his experience of where he started and the accomplishment that he’s been able to do, down in the STEM path, was really neat. And that summer was my final decision that I’m “OK, I know I want to be an engineer.” What’s interesting is I ended up choosing chemical engineering, instead of mechanical, which a lot of people, you know, based on all the experience that led me up to be an engineer, they asked me why I didn’t choose mechanical engineering. And I think one of the reasons why I chose chemical engineering is it’s very process-based. So one thing needs to happen, and there’s different inputs to that one step, and that step has an end-to-end reaction to it, right? So certain things need to happen in step one in order for step two to occur. And however the inputs happen in step one, it’s gonna affect the rest of the process. Honestly, very different than what I thought it was really gonna be. But what’s neat about chemical engineering is that it’s one of the most versatile engineering majors that you can have. Chemical engineering, because you work with a lot of process bases. Everything has a process, right? Everything needs to start with step one, and with, you know, step 10, whatever. And it’s all about optimization and improvement along those processes. So you can really take chemical engineering principles and apply ’em to different areas of a career, which is essentially the experience that I had in college. I had three internships with Dow Chemical where I did environmental health and safety, production, and supply-chain improvement. I then did research and development with Clorox. And then I did manufacturing engineering with General Mills. So really different job roles, different aspects, but same methodology applied.
Eric Cross (05:36):
I feel like there’s so much that you just said, <laugh> and I was trying to always, “I wanna ask him about that!” And in there, what I heard was there was a real pivotable, pivot moment in your life. Was the club…or was it a club, the robotics program? Or was that a class?
Juan Vivas (05:53):
You know, it was actually…it was VEX Robotics, specifically.
Eric Cross (05:56):
It was VEX! OK. Yeah, yeah. Really popular. And they still have it; I think we actually have some downstairs. So it was a club, and not necessarily a formal environment, where you were able to build. And it’s both collaborative and competitive, right? Like, there’s both aspects.
Juan Vivas (06:11):
Yep. Yep.
Eric Cross (06:11):
And, and then you had access to one of the only two facilities in the country that have these…were they buoyancy tanks?
Juan Vivas (06:20):
Buoyancy tanks, yep.
Eric Cross (06:21):
And there’s this book, Malcolm Gladwell’s Outliers, and then another similar book called Balance. It talks about how some of these innovators, like Steve Jobs and, and Bill Gates, they had access to things that other people didn’t. So, like, Bill Gates, I think at the University of Washington, had a computer that, you know, no one else did. And Jobs had one at, like, Hewlett-Packard. So it gave you this awesome headstart, where you’re able to test things in a real-life environment that kind of transfers into real-world skills. And then a few internships, so like, internships and mentors. So you had these people in the industry or people who were front-runners that were able to pour into you and give you these opportunities. And so it’s really neat to see how a program that starts as a club, kind of a competitive thing that introduced you to it and hooked you, then led to unfolding all of these opportunities that ultimately led you up to being here. And there’s one part—in looking at your LinkedIn profile, there’s a couple of really cool things that stand out. There’s a lot of cool things, but there’s two that really stood out. So one, working at SpaceX, and we’ll talk more about that, but I wanna go to General Mills and Cinnamon Toast Crunch. Because Cinnamon Toast Crunch is amazing.
Juan Vivas (07:39):
Yeah.
Eric Cross (07:39):
And you were part of the supply chain for that. In my head, I’m thinking, OK, like, what is he like responsible for? Like, getting the cinnamon and sugar?
Juan Vivas (07:51):
<Laugh>
Eric Cross (07:51):
What was, what did your job entail, when you were running that?
Juan Vivas (07:55):
There, I didn’t even know what I was gonna be doing until my first day. It was just, whatever the business need is, that’s where you’re gonna be put. So this was actually a high-priority plan for General Mills. And the production line that made Cinnamon Toast Crunch was split up into processes. So you have, they call it the process-process side, which is like literally raw materials, like making the cereal from scratch, baking it, adding the sugar, and then sending it to be packaged. And then you have the packaging-process side. so I was then placed as a packaging process lead, for the packaging side of that production line. So I was accountable for two packaging lines that packed out Cinnamon Toast Crunch. And that is where—that was actually my first real, you know, call it “real job,” like graduated college, going straight into the industry. I was a process lead for the packaging side of Cinnamon Toast Crunch.
Eric Cross (08:54):
So you went from cereal to rockets, <laugh>, which which is an amazing trajectory to have.
Juan Vivas (09:03):
Yeah. Yeah.
Eric Cross (09:04):
And when you kind of mentioned, back in your story about medical school, and, you know, it’s kinda like, what you see people doing, and you’re “OK, this is what I think I wanna do.” And then we have a perception in our mind about what a certain job’s gonna be like. And then reality hits. I think a lot of—when I ask my students, “What do you wanna do?” They think, like, “lawyer!” and when they think “lawyer!” they’re like, “I’m good at arguing!” Right? And until they find—until they talk to some lawyers and they find out like what that career can look like.
Juan Vivas (09:28):
Yeah.
Eric Cross (09:28):
You’re not just in the courtroom showing off your arguing skills. But, like, an engineer, when I talk to my students about what does it mean to be an engineer, often it’s very linear. It’s “I build bridges,” or, you know, maybe cars, but you’re a supply chain engineer. And, and that’s something that I think, now more than ever, it’s probably an incredibly critical role, especially considering that all of these supply constraints. Can you—what is a supply chain engineer? And what does it look like in your day-to-day? How is engineering rolled into that?
Juan Vivas (10:03):
Yeah, yeah. I think that’s an excellent question. I, too, once thought that engineering was just “I’m gonna be actually making something physical,” and like being super engineer-y about it. But, to me, based on my experience so far, I think the best way to put it: An engineer is a technical problem solver. As a supply chain engineer, specifically right now in my role at SpaceX…you know, as you can guess, the supply chain in the entire world is crazy. There’s no raw materials anywhere, and nothing can ever get on time. And so what I work on is I help our suppliers develop processes to meet the design criteria that we set up for like a specific part. As my job as a supply chain engineer, it’s “Can I take this design and make it manufacturable?” Right? “Can I go to any supplier and can they actually make this to the tolerance that the design engineer set them to be?” Nine out of 10 cases, the answer is no, essentially, is the best high-level way to put it.
Eric Cross (11:10):
When you’re solving these problems, is it this iterative process of going back and forth? Or is it just this aha-moment when you finally figure things out? ‘Cause I imagine they’re coming up with a design; you’re going back and saying, “Can this be manufactured?” or “Can it be done?” They’re saying no 90% of the time. And then are you the one responsible for kind of iterating on this, or changing it and then going back to them and telling them, asking them, until you get a yes? Is that—
Juan Vivas (11:33):
Yep. Yep, yep. Exactly. So we go through a process called Design for Manufacturing, DFMing. And where I essentially take, you know, the design engineer’s proposal, and then I have conversations with the suppliers, and then, that’s where the iteration begins. Where we go back and forth, back and forth, until we kind of meet in the middle to have something that can be manufacturable. Most of the times, in my experience, suppliers will always tell you no, just because they always want something that is manufactured really easily. And so you just gotta learn through experience. Like, when are they actually telling you something that’s a fact, versus when they’re just trying to you know, get out of a tolerance, or that “all right, all right, they mentioned that would just like make their jobs a little bit more difficult.”
Eric Cross (12:17):
So I’m hearing like there’s soft skills that are woven into the technical skills that you also need to be able to have.
Juan Vivas (12:23):
Oh, yes, absolutely. Yeah. I think, you know, as an engineer—and this is something, again, that I feel like you can only learn through experience—you’re gonna see that it’s not just you working to solve this one problem. Especially for a supply chain engineer. You’re talking with marketing; you’re talking with an industrial design team; you’re talking with logistics; you’re talking with procurement, materials management—just a whole set of people that don’t necessarily have technical background. Right? So sometimes, depending on the audience that I’m targeting, I’m always very, very peculiar on what is my target audience, right? How can I—how deep in my technical knowledge do I need to go? Because if I just, you know, talk straight Engineer, they either don’t care or they’re gonna be really confused about what I’m saying. So there is a stronghold of soft skills that definitely go into engineering, which I think are really important to communicate, you know, to, let’s say, students that are really interested in engineering. So you can be extremely smart and intelligent and really good at problem-solving, but if you don’t have those soft skills that you apply in the real world—’cause in the real world, you’re never only gonna be working with engineers, no matter like where you’re at—so having those soft skills to be able to manage with different backgrounds and different sort of people and different ways of thinking, it’s, I feel, really critical, for, for an engineer in the real world.
Eric Cross (13:50):
No, I think that’s a great point. It reminds me of teaching! And so many other professions where your ultimate goal is to really pour into this person in front of you and help develop them and create a sense of inquiry and wonder and personal growth and inspiration. But you’re also working within constraints and people and relationships. You know, you have your other teachers, you have parents, you have administrators, you have a district, you have communities, stakeholders. You have all of these different dynamics that you have to kind of navigate in order to ultimately help this child thrive. Versus just, like, being in the classroom: “OK, I just got <laugh>, the hundred or 200 students, just you and me. That’s it.” But that’s not the real world. And there’s this report that came out, I think Google ran it, Project Oxygen and Project Aristotle, and they asked the question, “What are the most effective traits of a good team and a manager?” And the top seven skills were all soft skills. So it is like exactly what you’re saying, where, yeah, it’s great that you have this technical aptitude, but if you’re not able to work with other people, problem-solve together, work with people of different backgrounds and perspectives, then you’re gonna run into some roadblocks. And that kind of dovetails, like, looking at things like if you looked at education from the perspective of an engineer. So you’re all about optimizing, right? Optimizing, working with what you got. When you look at education, are there any things that you would optimize to help improve the experience of students? Like, looking back, that you would fine-tune, that you think could provide better outcomes in the classroom?
Juan Vivas (15:28):
You know, I feel…I don’t know. Obviously I’m not a teacher. And I’m sure teachers just have so much stuff going on. But I think just like, finding…giving a chance to those students that you see a lot of potential in and really taking the time to mold them. You know, I did have a teacher who was able to mold me and give me that kind of one-on-one personal experience, right? I think honestly to me it just comes down to mentorship, and motivating students on what, you know, they’re passionate for. Like, putting them in front of engineers, right? Like finding engineers to come volunteer and explain to them. I genuinely believe it just takes one spark to really get a student on a trajectory where they can make an impact in the future. So to me, it comes down to, really, exposure. How much are you really exposing your students to…you know what, something I’ve learned, when I joined SpaceX, is that Elon doesn’t believe—well, you know, there there’s a lot of things that Elon believes and not believes in; there’s a whole different type of conversation!—but he doesn’t think that you can just take a curriculum, let’s say, and just apply it massively to everyone and expect like everyone to be it. That’s just naturally not how it works, right? Students learn at different paces; they have different sort of interests. This is actually why he created his own school for his kids in LA, called Ad Astra. You know, if you take that mentality, what that school is doing is that they’re working at the students’ pace and at the student’s interests, right? And I actually have a coworker who has his kids in that school. And I mean, these are one of the most brilliant kids I’ve ever known. Like, they are taking differential equations in the eighth grade. And I didn’t know what differential equations was until I was in college already and they told me, “This is a class you have to take.” <Laugh>. But it’s finding that crossway where, where is the curiosity of the student? What are they really interested in? and exposing them to that.
Eric Cross (17:51):
Yeah. And what I’m hearing of that is, in teacher-speak, a lot of personalized learning. Like you were talking about…is it Ad Astra?
Juan Vivas (17:59):
Ad Astra? Yep.
Eric Cross (18:01):
Ad Astra. You know, every student learns in their own way and they develop knowledge in their own way. And being able to personalize learning according to the students’ abilities and needs, and then accelerate or slow down, really produces some amazing effects. I know this is something that we as teachers try to do with the classroom. Scaling it is the challenge. But it’s great because even with people who are in charge of policy or people who have decision-making ability, hearing people from the top down saying, “Hey, look, this is what worked for me. This is how I was able to become successful. I had a teacher that was able to be a mentor to me because they knew me, they had a relationship with me, they were able to tap into my passions and use those passions to drive me to do or put me in programs that I might not have known about because they, they knew who I was.” And it’s not one-size-fits-all for everyone. So having—maybe it’s curriculum or learning experiences that are kind of modular, where students are able to maybe try on different things and get that exposure, I’m a big, big believer, like you are, in mentorship. That was a huge, huge thing in my life. Having mentors. It’s the reason why I became a science teacher. In seventh grade, I had a mentor who had us doing college-level science, you know, at UC San Diego. And it completely changed the trajectory of my life, in a direction that I wouldn’t have had without him. So I think that’s great. And it’s something that we as teachers would appreciate hearing. Going back to what you said…earlier you said your wife is a supply chain engineer as well. And so that means that there’s two people who are process-minded in the household. And this is kind of a lighter question, but I gotta wonder, do you have the most optimized flow for grocery shopping? <Laugh> Because…
Juan Vivas (19:49):
Yeah, I think we don’t spend more than like 20 minutes at a grocery store. Mind you, we only shop at Trader Joe’s and we have a very specific list before going in. And if you ever shop at Trader Joe’s, you just know where everything is ’cause it’s always there and it’s small, right? But yeah, like we’re, we’re in and out in like 15, 20 minutes. It’s great.
Eric Cross (20:11):
I love it. I love it. I feel like I’m that way by design. I go in with a purpose and this is exactly what I want. I know where the cookie butter is, <laugh>, I know where my coffee is, and then, OK, I’m in and out. Apple Pay or whatever I’m using. And then we’re good to go. Do you think…so as someone listening to this or some people even just becoming aware of supply chain engineering, what advice would you give someone that’s interested in pursuing this career path? If you maybe reverse-engineered your process, knowing what you know now, you were gonna give advice, you were that mentor, what are just some kind of tips or ideas or thoughts or trajectories that you’d think that they should aim for? I’m assuming like robotics….
Juan Vivas (20:56):
Yeah. You know, I think I would say definitely finding some sort of program that exposes you to a lot of things that you won’t be exposed to, like on a day-to-day basis, or something that you just can’t be exposed to naturally at school. And mentorship, honestly. I was born in Colombia and my parents were both—they’re still both professionals, but they were both professionals in Colombia. And when we moved to this country, this was like December of 1999. My parents started from scratch, and so they didn’t really grow up in the States, right? So when it was my time to go to college and do all of this stuff, it was just like me on my own figuring this stuff out. And, you know, they definitely made some mistakes when it came to college applications and whatnot. But once I was in college, I knew that the best way for my success was gonna be through mentorship. And that’s when I joined the, Society of Hispanic Professional Engineers, which is a nationwide organization. And each college, well, most college campuses, have their own chapter. In joining that, I was exposed to resume workshops, mock interviews—basically how do you even talk to a recruiter? Which is so critical, right? And personally that that organization was really what molded my actual professional career.
Eric Cross (22:19):
There’s this theme that I’m hearing, kind of weaving through this. And in addition to—as we’re talking about STEM and technical skills, in addition to that, there’s this thread that I’m receiving of…being able to form relationships with other people, for our students, is an important skill to teach and should be taught explicitly. Which isn’t…it’s not really a curriculum, right? Like, you don’t get tested on your ability to….conflict resolution or how to write an email or how to develop a relationship. And then the other part in I think what you just said is the aspect of community. Through this organization, you learned kind of some of these hidden rules, maybe I would call it.
Juan Vivas (23:04):
Yep.
Eric Cross (23:04):
It’s not that you didn’t have the…you had the aptitude. You had the drive. But there were these kind of hidden rules, and from moving to the US, you needed a community to be able to show you, so that you can kind of go through the proper steps.
Juan Vivas (23:16):
Exactly.
Eric Cross (23:17):
And so that created a lot of value for you.
Juan Vivas (23:19):
Yep.
Eric Cross (23:20):
Well, the last question that I have is, is just kind of a wondering. You have this awesome story, and the story continues to unfold. I gotta say, <laugh> I’m gonna be following your LinkedIn profile, because I think you just have kind of the coolest trajectory of going from, you know, General Mills, working in chemical engineering, and then ultimately it’s SpaceX. And every time I see the rocket taking off and landing, I’m gonna be thinking, thinking about you. So cool!
Juan Vivas (23:47):
Yeah. Yeah.
Eric Cross (23:49):
And personally, I have a hope that one day, one of my students will be at a company, you know, like SpaceX or Tesla or wherever, and one day I get to interview them and talk to them and see what they say. But the last question I want to ask is, is there, is there a teacher who inspired you, or a memorable experience that you have that made an impact on you?
Juan Vivas (24:16):
Yeah, yeah, of course. It was kind of you know, middle school going into high school. The way my school worked, everything was divided from pre-kindergarten, whatever, first to sixth grade, and then seventh grade to 12th grade. So I had a high school science teacher, Ms. Brown, Ms. Velda Brown, who, came from a small little island town on the east coast of Canada. Somehow landed, in the high school that I went to, to teach science. Going back to the beginning of the story where I mentioned that I figured whatever, I’ll go to med school. I played soccer, basketball, and, you know, I said, “I’ll figure it out once I graduate.” It might have been like life science in the eighth grade or something like that. But then she went on to teach me chemistry and physics as well. And when I was in the 10th grade, she approached me and she asked me if I wanted to join the robotics club. And I remember saying robotics? I don’t know. You know, naturally, in school, it’s different sorts of crowds: people that play sports and people that are like in like STEM clubs or whatever. And I was, “Ah, I don’t know; I don’t know how I feel about robotics; not really my thing….” But somehow she convinced me to join robotics. It’s me, coming into this group of kids that already knew each other, and they were all working on robotics. And I’m, “Yeah, I mean, I guess I’m just here to try this thing out.” It was a thing where we met every single Saturday at like seven in the morning. And there were times where I literally had to choose, “Do I go to like a soccer game or do I go to you help my team with robotics?” And I completely loved it. Like, I fell in love with the aspect of building something from scratch, and just making it operative. And she ended up just being a huge mentor for me in high school, actually. With her, with the help of her, I ended up opening the robotics club at my school. And before I left, we opened it up to middle schoolers. And then, you know, later, years later down the road when I was in college, I found out that it was now a whole-school thing. So there was an elementary robotics club at the school, the middle school one, and then the high school one were still a thing like years after I left. And that was like just so amazing to hear. But yeah, it was Ms. Velda Brown, my high school science teacher, that really took her time to mold me and get me into robotics, and really mentor me. And honestly, I’m sure you as teachers, you guys probably hear about it a lot, but you can have a lot of power in shaping a kid by just telling—believing in them, right? She believed in me so much that I would go on to be a successful engineer. And I’m. “OK, yeah, yeah, you’re just saying it.” But she spoke life into her students up to this day. I still speak about it with my wife, and when I’m in conversations about this, that if it wasn’t for my high school science teacher, I would not—well, no, I would probably not be an engineer right now.
Eric Cross (27:38):
Wow. Shout out to Ms. Velda Brown <laugh>. Would you say she spoke…I think one thing that just resonated with me is when you said she “spoke life” into you.
Juan Vivas (27:46):
Yeah.
Eric Cross (27:46):
That was really powerful. And I think we as teachers have that power and we don’t realize it. Because, you know, we get so we’re so familiar and living day-to-day, but we do have the power of life, speaking life, into our young people. And, yeah, that was—
Juan Vivas (28:03):
Absolutely, yeah. You know, I think obviously people grew up with different backgrounds, different communities, life situations, right? So imagine having like a student that is similar in that environment and then they just hear someone at their school, like, “Hey, you’re really good at this. why don’t you consider doing this?” And that’s when I feel teachers have that power. Where like they don’t necessarily know the background, but they can make that opportunity, or make that decision in the moment, to really shape a student’s life.
Eric Cross (28:37):
And we need to hear that. And I think, I hope that other teachers listening to this will be reminded that many times we don’t get to reap the harvest. We don’t get to see the <laugh> Juan Vivases at SpaceX. They just kind of go, and they disappear, and we hope for the best, and we get a new group. But every once in a while they come back, and we get to see what our watering or seed-planting was able to produce. And so, just know that you sharing your story for educators, and for definitely Ms. Brown, makes a huge difference and is a huge encouragement. So.
Juan Vivas (29:11):
You know, I think we touched on earlier, you know, how do I end up going from cereal to rockets, right? And I think it ties along with what I mentioned earlier of just taking—as an engineer, you’re really a critical problem solver, right? And you think that methodology. And if you find a way, you can apply it to different sectors. When I was doing a lot of like the packaging process stuff at General Mills, being a lead on a high-volume manufacturing line, what I do for SpaceX specifically, right now, I’m actually on the Starlink project. So if you’re up to date with Starlink, it’s, it’s essentially high reliable, fast internet that we’re providing to areas where usually people don’t have access to internet, right? Or maybe they do, but it’s extremely expensive. Because to an internet provider company, the benefit is not there, if they extend an entire internet fiber line out to their place because it’s only directed to them, right? So that’s, that’s essentially what Starlink is trying to solve. And this is the first time that SpaceX is facing a consumer packaging scenario. Before it was just rockets. And now they’re selling a product to consumers. They had never done that before, especially in a high-volume manufacturing setting. And so I am the supplier development engineer for all the consumer-facing packaging for the Starlink product itself. And that’s essentially how all those thoughts connected, where I had this experience coming from General Mills and packaging high-volume manufacturing. And then when Starlink started, they’re all, “Right, well, who knows anything about packaging?” Right? “We know so much about rockets, we need someone with this technical background.” And that’s essentially how I bridge over to SpaceX.
Eric Cross (31:11):
And so while you’re working at SpaceX, you’re working on Starlink, which I know you mentioned that—you said that it’s providing internet globally, which in and of itself, we—especially those of us that live in major cities—we kind of take for granted. Internet is like a utility. But we don’t maybe realize that in many parts of the world, internet is not reliable or even accessible.
Juan Vivas (31:33):
Right. Right.
Eric Cross (31:34):
I see every once in a while, I think, the StarlinK satellites sometimes are visible?
Juan Vivas (31:38):
Yep.
Eric Cross (31:39):
Low orbit?
Juan Vivas (31:39):
Yeah. Yeah. You can go—they’ll kind of be like a little train of bright stars that move along together. Yep.
Eric Cross (31:46):
And that must—that must feel…I mean, we all have jobs and we’re all doing different things, but you’re working on a project and you’re engineering something that actually can provide a lot of opportunities or close a gap in some parts of the world where they don’t have access to internet. They’re gonna be able to have access and be connected all over. I dunno, the word would be “existential.” Existential value. Like, what you’re doing is actually providing a service for people. Humanity. Like, addressing a critical need in many, many places around the world.
Juan Vivas (32:26):
Yeah. We’ve had stories where we have sent Starlink kids to a small school in a village in rural Chile, right in South America. And for the first time ever, they’ve had internet. We have supported disaster relief in Europe. I think this past summer, Europe had really bad floods. We sent Starlink kits out there. You know, the vision of working at an Elon Musk company and SpaceX and Starlink—this is all stuff that is being done for the first time in history. We have never, ever done anything like this before until now. And to be able to provide those that don’t have the access to—to your point, it’s kind of wild, right? Like we, we just take it for granted. “Oh yeah, I just have internet. Let me log on.” There are people on Earth right now that have never been on the internet. Or don’t even know what the internet is. And that’s essentially the, the gap that Startlink is starting to close.
Eric Cross (33:26):
Yeah. We think about that while my students are doing TikTok dances. <Laugh> And there are people who, you know, never, never been connected. And, it kind of makes me more like, just inside, if I can ask: What’s it like working at SpaceX? I showed my students what it’s like working at some of the Silicon Valley companies. ‘Cause just to show them there’s slides and food and, you know, they kind developed this ecosystem inside so that it’s really kind of homey to kind of keep you there, you know. When you’re working and there’s bikes and things like that. And that’s a very Silicon Valley type of thing. But, you know, in listening to you talk about SpaceX and Elon, you know, you’re with a really visionary kind of company, and when I hear you talk about it, there’s I can hear this passion, this, “we’re doing something.” Is that culture, like, pervasive everywhere? Are you around folks that kind of are on that same wavelength? Because I definitely get it from you as you talk about what you do.
Juan Vivas (34:28):
Yeah, yeah. Definitely. I think, as an engineer, you know, going to SpaceX and working at SpaceX, it’s essentially—personally, I believe right now in the US it’s like the mecca of engineering, right? Like, it is where engineering in this most, you know, shape and manner, it’s being applied. I think what’s really interesting is that the way that Elon looks at it is just iterate, and iterate fast, right? Like, fail and fail fast. I think as an engineer, you always want to have things perfect, right? And so you spend a lot of time in making a decision or investigating something or whatever. And working at SpaceX is the complete opposite. It’s just you know, “Assume, state your assumptions—like, what are you assuming right now? What are the risk at it? And just make a decision and then see what the result is.” You know, so it’s an environment where you learn, really quick.
Eric Cross (35:28):
You said something that I think was powerful and I hope, I think <laugh>, this is definitely, I’m gonna get a clip of this <laugh> of you saying it. Because it speaks directly to, I think, what a lot of students struggle with in the classroom, is there’s this competition or feeling that you always need to be right. And you need to be right the first try, on the first time. And a lot of times it’s because students will compare themselves to each other, or there’s a tremendous amount of pressure to be successful. But you said, “Fail and fail fast, iterate, state your assumptions.” And it sounds like this critical part of being an engineer or in what you do, like there’s no room for ego or attaching your identity or your sense of value or worth or ability to whether you’re able to solve a problem in the first try.
Juan Vivas (36:13):
Yep.
Eric Cross (36:14):
Like, you have to be OK with the cycle, is kind of what I’m hearing from you. Is that, is that right?
Juan Vivas (36:19):
Yep. Exactly. It only took six months to develop the product from scratch and launch it to the public, which is insane. Nowhere in the world will any company ever iterate that fast and come up with a brand-new project. But it’s because of that mentality—like you’re saying, it’s not about like just trying to make it perfect and have all this information. And I think Elon has learned this personally, you know, through Tesla and the beginning of SpaceX. It’s, “I can wait to have all this information, and most likely I’m still gonna be wrong after I make the decision.” So it’s, “Might as well take the risk, do the decision, and then just see where you learn from it, right?” And then you keep applying that, applying that. So it’s like you iterate, iterate, iterate, iterate until you get what you want.
Eric Cross (37:00):
I think this is even, like, great advice. I’m taking this personally because I get paralysis by analysis <laugh>.
Juan Vivas (37:06):
Yep.
Eric Cross (37:07):
You know, I’ll research something to death but then not actually execute. Like, I need to make a decision and do it and then course-correct along the way. Somebody once told me it’s a lot easier to turn a moving car than it is a car that’s sitting still. And so as you’re kind of flowing, you’re just making these adjustments along the way until you end up on the path that you want to be. So I think that there’s so many gems in the things that you’re saying right now. What I’m thinking through the lens of my seventh graders that want to work in any STEM field—I mean, really, any field in general, but especially engineering, especially the STEM fields—knowing that, pick it, make a decision, move forward, and then course-correct along the way. That’s what science looks like in the real world.
Juan Vivas (37:49):
Yep. Exactly. Yep. And definitely most important—and I feel like this is sometimes where, not necessarily education in general, but it’s just, we want students to, “OK, you need to get it right the perfect time, right?” But it’s like, every student is gonna think differently. A student is gonna take a different assumption based on their background and experiences. And I mean, you know, we can go a lot deeper in that, but the way a student is shaped, they’re gonna take certain assumptions. So that’s where it gets interesting. OK, why are you assuming that? Where’s your thought process in this?
Eric Cross (38:25):
And we all come from different backgrounds and mindsets and filters and biases that cause us to look at something a certain way. And it’s not just like calling it out, just going, “Hey look, this is what it is.” Like autopsy without blame, this is what I’m working with. Let’s discuss it openly. Right? And if we started that process earlier, you know, younger, in classrooms, we can de-stigmatize the right answer being the best answer more, as opposed to focusing on process as opposed to outcome. And then you kinda get used to wanting to go through the process. I look at it like video games and I talk to my students. I say, “You know, you don’t pick up a video game that’s brand-new and then play it and then you die once and you’re ‘Ah, I’m never gonna play this game again.’ You know, it just doesn’t work that way. You’re going through this iterative process, and no matter what you play, you’re trying things differently. You’re data collecting. And then you’re making new decisions based on the data that you collected.” And for some of my kids, they’ll just raise their hands, say, “No, I just get mad and throw the controller across the room.” <Laugh> But I go, “Yeah, and then you’ll try it again.”
Juan Vivas (39:33):
The best way to know how not to do something is to fail. And so you already…I mean, what is that famous quote? I think that’s why Thomas Edison’s, “Oh, I, did not fail 99 times. Right? I only found 99 times…” I mean, that is that is true. And I feel like at work in a SpaceX, that is something that probably the core of it comes from there. It’s you know, any failure, quote unquote, that you may take it as a failure, it’s really not. You’re just “OK, we, we tried that. It didn’t work. Like what are we gonna do next?” So it’s just like taking that learning and like moving off with it quickly.
Eric Cross (40:09):
I heard a couple of teachers say, “Things fail: First Attempt In Learning: F A I L.” And then another teacher, one of my mentor teachers, she said, “There’s no such thing as failure, just data, in science.”
Juan Vivas (40:20):
Mm-hmm. <affirmative>. Exactly. Yep.
Eric Cross (40:23):
And so I’ve always taken that to heart. And I share that with my own students, just, “A ‘no,’ a lot of times, will tell you more information than a ‘yes.’” ‘Cause if something works in the first try, you may not exactly know why it worked. It just did.
Juan Vivas (40:34):
Yeah. Yep.
Eric Cross (40:37):
So yeah. Well, I went on your time, brother. Dude. <laugh>. The time flew. It was…
Juan Vivas (40:46):
Yeah.
Eric Cross (40:47):
There were so many things I was trying to write out as you were talking, that I just felt like, “This guy is sharing so many gems!” But yeah, I want to thank you for taking time outta your day and for sharing that information for your passion for what you do. And, I don’t know, I think that students and teachers that listen to this will get an insight from a perspective that really matters. ‘Cause ultimately we’re, we’re trying to really prepare our students for real life. Maybe I’ll email you privately if I order a Tesla, if you can move me higher up the Cybertruck line. <laugh>
Juan Vivas (41:22):
Yeah. No promises.
Eric Cross (41:24):
<laugh>
Juan Vivas (41:25):
Yeah. No, I appreciate you guys having me, having me here, and be able to speak on my experience. And hopefully it sparks a couple, one, even if it’s just one teacher that will spark another student, that is already success there. So.
Eric Cross (41:42):
Well I know, I know what you said resonates with me and it fills my cup. And I’m excited. So I’m already thinking of some ideas of things that I can do, just because of this conversation, and I know other people will as well. And, again, this is Juan Vivas, who’s a supply development engineer at SpaceX. He’s worked at some amazing places. And someone who believes deeply in not only the power of the technical skills, but the heart skills, and how community makes a huge impact in his life. It made a huge impact in him ultimately becoming a scientist, and now working on a project at SpaceX, Starlink, that is going to provide access to the world, to the web. And that’ll ultimately help us solve more problems and innovate and create some solutions that will benefit everybody. Thank you, sir. Appreciate you.
Juan Vivas (42:30):
Yeah, thank you. Thank you so much, Eric. Appreciate it.
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Meet the guest
Juan Vivas is a chemical engineer currently working as a Supplier Development Engineer at SpaceX. Juan got his start at the University of Florida, where he led the Society of Hispanic Engineers (SHPE) as vice president. He’s worked for companies like Clorox, Dow Chemical, and General Mills. Juan lives in Los Angeles, California with his wife and two dogs.
About Science Connections: The podcast
Welcome to Science Connections: The Podcast! Science is changing before our eyes, now more than ever. So…how do we help kids figure that out? We will bring on educators, scientists, and more to discuss the importance of high-quality science instruction. In this episode, hear from our host Eric Cross about his work engaging students as a K-8 science teacher.
Customer Privacy Policy
Last Modified: January 23, 2026 | Update History
Most recent update: This Privacy Policy has been updated to address additional rights for individuals in the European Union/UK.
We advise you to read this Privacy Policy in its entirety, including the jurisdiction-specific provisions in the appendix. Click here to review Our U.S. Notice At Collection.
Customer Privacy Policy: K–12 Schools
Who We Are
Amplify Education, Inc. (“Amplify”) is leading the way in next-generation curriculum and assessment. Amplify’s programs provide teachers with powerful tools that help them understand and respond to the needs of each student and use data in a way that is safe, secure, and effective.
Our Products and Services
Amplify’s products support classroom instruction and learning and include Amplify CKLA, Amplify ELA, Amplify Caminos, Amplify Science, Amplify Desmos Math, Boost Reading, Boost Math, mCLASS, Mathigon, associated professional development and tutoring services, and services at classroom.amplify.com (for creating and assigning activities) and student.amplify.com (for use of the activities or curricula as directed by an instructor), and any other product or service that links to this Privacy Policy (together, the “Products”).
Our Approach to Student Data Privacy
In the course of providing the Products to Schools and their Authorized School Users, Amplify collects, receives, generates, or has access to Student Data (defined below). We consider Student Data to be confidential and we collect and use Student Data solely for educational purposes in connection with providing our Products to, or on behalf of the School as described in this Privacy Policy and our Agreements (defined below). We work to maintain the security and confidentiality of Student Data that we collect or store, and we enable Schools to control the use, access, sharing, and retention of Student Data.
Our Products are geared towards K–12 students (“Students”), and the educators, agents and staff members who use the Products as authorized by their School (“Educators”). Information that directly relates to an identifiable Student (“Student Data”) is owned and controlled by the School, and Amplify receives Student Data as a “school official” under Section 99.31 of the Family Educational Rights and Privacy Act of 1974 (“FERPA”) for the purpose of providing the Products hereunder. In addition, we rely on the School acknowledging that it is acting as the parent’s agent and consenting on the parent’s behalf to process personal information of Students under the age of 13 (“Child Users”) in accordance with the Children’s Online Privacy Protection Act (“COPPA”).
Our collection and use of Student Data is governed by our Agreements with Schools, including this Privacy Policy (“Privacy Policy”), and applicable laws which may include FERPA, COPPA, the Protection of Pupil Rights Amendment (“PPRA”), as well as other applicable federal, state, and local privacy laws and regulations (“Applicable Laws”). As noted above, with respect to FERPA, Amplify receives Student Data as a “school official” under Section 99.31 of FERPA for the purpose of providing its Products, and such Student Data is owned and controlled by the School.
Schools may provide authorization in two ways:
- by the School agreeing to our Customer Terms and Conditions located at amplify.com/customer-terms or another written agreement between Amplify and the School, as applicable; or
- by an Educator agreeing to the Acceptable Use Policy located at amplify.com/acceptable-use-policy/ (“AUP”) on behalf of the School as outlined in the AUP.
In each case, we collect Student Data and provide these Products solely for the use and benefit of the School and for no other commercial purpose. We require all Schools to review this Privacy Policy, available at amplify.com/customer-privacy, and to make a copy of the Privacy Policy available to the parents or guardians of Child Users.
We also provide limited opportunities for individual users to sign up for an account for use of our Products at-home or otherwise outside of the authorization of a School (“Home Users”). See the Appendix–Supplemental Disclosures for additional information that applies to our Home Users.
What This Privacy Policy Covers
This Customer Privacy Policy (“Privacy Policy”) describes how Amplify collects, uses, and discloses personal information through the provision of Products.
For purposes of this Privacy Policy, “you” and “your” means Authorized Users (defined below).
This Privacy Policy does not apply to Amplify’s handling of:
- information collected from users of Amplify’s company website, which is governed by our Website Privacy Policy.
- job applicant data that we process in accordance with our applicant privacy notice.
There may be different contractual terms or privacy policies in place with some Schools. Such other terms or policies supersede this Privacy Policy for information collected or released under those terms. If you have any questions as to which legal agreement or privacy policy controls the collection and use of your personal information, please contact us using the information provided below. Unless expressly superseded, this Privacy Policy is incorporated into and is subject to the Agreement that governs your use of the Products.
Our Role
Amplify as a processor/service provider: Our School customers are the controllers of Student Data (as well as certain other Educator personal information to the extent required by law or Amplify’s agreement with the School) (together “School Data”).
Amplify acts as a processor/service provider for our School customers with respect to School Data, which means when we use School Data, we do so solely on the instruction of the School. School Data is subject to the School’s privacy policies; therefore, you will need to contact the School directly if you have any questions or would like to exercise your rights with respect to School Data.
Amplify as a controller: We are the controller of all other personal information we collect from non-Student Authorized Users (“Amplify Data”) and can be reached by email at privacy@amplify.com or by mail at Amplify Education, Inc., 55 Washington St.#800, Brooklyn, NY, 11201.
Policy
1. Definitions
Capitalized terms not defined in this section or elsewhere in this Privacy Policy will have the meaning set forth by Applicable Laws.
“Agreement” means the underlying contractual agreement between Amplify and the School.
“Authorized Users” means all users of our Products, including Authorized School Users, parents and legal guardians, and Home Users.
“Authorized School Users” means Students and Educators.
“Local Education Authority” means a local education agency or authority, school district, school network, independent school, or other regional education system.
“Non-Student Data” means information that is linked or linkable to Authorized Users who are not Students.
“School” means the Local Education Authority or State Agency.
“State Agency” means the educational agency primarily responsible for the supervision of public elementary and secondary schools in any of the 50 states, the Commonwealth of Puerto Rico, the District of Columbia, or other territories and possessions of the United States, as well as a national or regional ministry or department of education in other countries, as applicable.
2. What personal information do we collect?
When you access or use our Products, you may choose to provide us with personal information, including Student Data. This information may be provided to us directly (e.g. when an account is created or through communications with us) or through your interactions with our Products.
Student Data. Below is a list of the categories of Student Data that may be collected by Amplify or its Products, either directly or through the Authorized School User’s use of the various features and configurations of the Products:
- Identifier and Enrollment Data, such as name, email, school / state ID number, username and password, grade level, homeroom, courses, teacher names.
- Why? Most of Amplify’s Products require some basic information about who is in a classroom and who teaches the class—Student or teacher Identifier and Enrollment data. This information is provided to Amplify by the School, either directly from the School’s student information system or via a third party with whom the School contracts to provide that information.
- Demographic Data, such as date of birth, socioeconomic status, race, national origin, and preferred or primary language.
- Why? To support school instructional and reporting requirements, Amplify’s Products allow Schools to view reports and analyze data using Demographic Data. Generally, Demographic Data is provided on a voluntary basis by the School. For example, a School may wish to analyze Student literacy assessment results based on English Language Learner status to better tailor classroom instruction, and in that case, the School may provide Demographic Data to enable that reporting.
- School Records, such as grades, attendance, assessment results, and whether an Individualized Education Plan (IEP or local equivalent) is in place.
- Why? Some of our Products support grading assignments and administering formative, diagnostic, and curriculum-based assessments. Teachers use that information to support Students’ progress in the program or help with instructional decisions. We do not collect specific details from an IEP, nor do we collect protected health information or other sensitive information.
- Schoolwork and Student Generated Content, which includes any information contained in Student assignments and assessments, including information in response to instructional activities and participation in collaborative or interactive features of our Products, such as Student responses to academic questions and Student-written essays, as well as images, video, and audio recordings.
- Why? As part of the digital learning experience, some of our Products may enable Students to write text and create and upload images, video, and audio recordings. For example, in Amplify ELA, students may write essays or submit short-form responses in our platform as part of a lesson on literature. As another example, in Boost Reading, student interactions with reading skills games are recorded to keep track of the student’s progress to level up in the program and to provide visibility to teachers on how students are mastering the skills.
- Teacher Comments and Feedback, such as scores, written comments, or other feedback that Educators may provide about Student responses or student course performance.
- Why? To enable teachers to track the performance and provide feedback to their students.
- Non-Student Data. We may collect the following types of personal information from all other Authorized Users:
- Contact Information, such as name and email address, as well as grade level taught, school name and school location, whether you are an Educator or Home User that creates an account or uses our Products or communicates with us.
- Account Information, such as user login and password, for account creation and access purposes.
- Survey Responses, which you provide in response to surveys or questionnaires.
- Device and Usage Data. Depending on the Product, we may collect certain information about the device used to connect to our Product, such as device type and model, browser configurations, and persistent identifiers, such as IP addresses and unique device identifiers. We may collect device diagnostic information, such as battery level, usage logs, and error logs, as well as usage, viewing, and technical information (e.g., email open rates), such as the number of requests a device makes, to ensure proper system capacity for all Authorized Users. We may collect IP addresses and use that information to approximate device location to support operation of the Product. To the extent that we collect this information, this data is solely used to support operation of the Product and is not linked to Student Data. For purposes of clarity, Amplify does not use Student Data for marketing or advertising purposes (see section 6 of this Privacy Policy for more information about our commitments regarding Student Data).
- Why? We use this information to remember returning users and facilitate ease of login, to customize the function and appearance of the Products, and to improve the learning experience. This information also helps us track product usage for various purposes, including website optimization, to ensure proper system capacity, troubleshoot and fix errors, provide technical assistance and customer support, provide and monitor the effectiveness of our Products, monitor and address security concerns, and compile analytics for product improvement and other internal purposes.
- How? Cookies and Similar Technologies. We collect device and usage data through “cookies,” Web beacons, HTML5 local storage, and other similar technologies, which are used in some of our Products solely to support operation of the Products as described above. While we may use third party cookies and similar technologies for advertising and marketing purposes on our website (in accordance with our Website Privacy Policy), we do not permit such tracking technologies to be present on Student-facing portions of the Products. In particular, we only use the following types of cookies in our Products:
- Strictly necessary cookies – These are cookies that are required for the operation of our websites and applications that host our Products. They include, for example, cookies that enable you to log into secure areas of our Products. These cookies are not generally stored beyond the browser session and are less likely to include personal information. This category of cookies cannot be disabled.
- Functionality Cookies – We use these cookies so that we recognize you on the websites and apps that host our Products and remember your previously selected preferences. These cookies are stored on your device between browsing sessions but expire after a pre-defined period. These cookies enable us to “recognize” you when you use our Products, including your preferences such as your preferred language, time, and location. A mix of first party (placed by us) and third-party cookies (placed by third parties) are used.
- Performance Cookies – These cookies help us and service providers acting on our behalf compile statistics and analytics about users of our Products that are accessed via websites and apps, including Device and Usage Information.
- Learn how to opt out of cookies and similar technologies by reading the “What Rights and Choices Do You Have?” section of this Privacy Policy below.
3. How do we use personal information?
Student Data. Amplify uses Student Data for educational purposes, to provide the Products, and to ensure secure and effective operation of our Products, including:
- to provide and improve our educational Products;
- to support School and Authorized School Users’ activities;
- to ensure secure and effective operation of our Products;
- for purposes requested or authorized by the School or Authorized School User or as otherwise permitted by Applicable Laws;
- for customer support purposes, to respond to the inquiries and fulfill the requests of the School and their Authorized School Users;
- to enforce Product access and security controls; and
- to conduct system audits and improve protections against the misuse of our Products, or to detect and prevent fraud and other harmful activities.
- to enable the adaptive and personalized learning features of the Products.
Non-Student Data. Amplify may use Non-Student Data for the purposes for which Student Data is used as set forth above. In addition, Amplify may use Non-Student Data to provide customized content, advertising and marketing in limited circumstances (e.g. to periodically send newsletters and other promotional materials) directed to Educators and Home Users. For sake of clarity, we do not use Student Data for marketing purposes and we do not direct marketing to Students. Amplify may also use Non-Student Data for internal research and analytics, including generating insights on the use of our Products by Educators in certain Schools so that we can better serve those communities. We will also use Non-Student Data as otherwise required or permitted by law, or as we may notify you at the time of collection. Learn how to opt out of these communications by reading the “What Rights and Choices Do You Have?” section of this Privacy Policy below.
Amplify may use aggregate or de-identified data as described in the Aggregate/De-identified Data section below.
4. To whom do we disclose personal information?
Student Data. We disclose Student Data to third parties only as needed to provide the Products under the Agreement, as directed or permitted by the School or Authorized School User, and as required by law. Such disclosures may include but are not limited to the following:
- to other Authorized School Users of the School entitled to access such data in connection with the Products;
- to our service providers, subprocessors, or vendors who have a legitimate need to access such data in order to assist us in providing or supporting our Products, such as platform, infrastructure, and application software. We contractually bind such parties to protect Student Data in a manner consistent with those practices set forth in this Privacy Policy and in accordance with Applicable Laws. A list of Amplify subprocessors is available at https://www.amplify.com/subprocessors;
- to comply with the law, respond to requests in legal or government enforcement proceedings (such as complying with a subpoena), protect our rights in a legal dispute, or seek assistance of law enforcement in the event of a threat to our rights, security, or property or that of our affiliates, customers, Authorized Users, or others;
- in the event Amplify or all or part of its assets are acquired or transferred to another party, including in connection with any bankruptcy or similar proceedings, provided that successor entity will be required to comply with the privacy protections in this Privacy Policy with respect to information collected under this Privacy Policy, or we will provide the School with notice and an opportunity to opt out of the transfer of such data prior to the transfer; and
- except as restricted by Applicable Laws or contracts with the School, we may also share Student Data with Amplify’s affiliated education companies, provided that such disclosure is solely for the purposes of providing Products and at all times is subject to this Policy.
Non-Student Data. Amplify discloses Non-Student Data for the purposes for which Student Data is used as set forth above. Amplify may also disclose Non-Student Data as otherwise required or permitted, or as disclosed at the time of collection. Please note that we do not share mobile information or opt-in consent with third parties / affiliates for their own marketing or promotional purposes.
5. Aggregate/De-identified data
Amplify may use de-identified or aggregate data for purposes allowed under FERPA and other Applicable Laws, to research, develop, and improve educational sites, services, and applications and to demonstrate the effectiveness of the Amplify Products. Amplify will not attempt to re-identify de-identified data. We may use aggregate information (which is information that has been collected in summary form such that the data cannot be associated with any individual) for analytics and reports. For example, our promotional materials may note the total number of students served by our programs in the prior year, but that information cannot be used to identify any one student. We may also share de-identified or aggregate data with research partners to help us analyze the information for product improvement and development purposes.
Records and information are de-identified when all personal information has been removed or obscured, such that the remaining information does not reasonably identify a specific individual. We de-identify Student Data in compliance with Applicable Laws and in accordance with the guidelines of NIST SP 800-122. Amplify has implemented internal procedures and controls to protect against the re-identification of de-identified Student Data. Amplify does not disclose de-identified data to its research partners unless that party has agreed in writing not to attempt to re-identify such data.
6. Data prohibitions, Advertising, Advertising limitations
Amplify will not:
- sell Student Data to third parties;
- use or disclose Student Data to inform, influence, or enable targeted advertising to a Student based on Student Data or information or data inferred over time from the Student’s usage of the Products;
- use Student Data to develop a profile of a Student for any purpose other than providing the Products to a School or Authorized School User, or as authorized by a parent or legal guardian;
- use Student Data for any commercial purpose other than to provide the Products to the School or Authorized School User, or as permitted by Applicable Laws.
7. External third-party services
This Privacy Policy applies solely to Amplify’s Products and practices. Schools and other Authorized Users may choose to connect or use our Products in conjunction with third-party services and Products. Additionally, our sites and Products may contain links to third-party websites or services . This Privacy Policy does not address, and Amplify is not responsible for, the privacy, information, or other practices of such third parties. Schools should carefully consider which third-party applications to include among the Products and services they provide to Students and vet the privacy and data security standards of those providers.
Authorized Users may be able to log in to our Products using third-party sign-in services such as Clever, ClassLink or Google. These services authenticate your identity and provide you with the option to share certain personal information with us, including your name and email address, to pre-populate our account sign-up form. If you choose to enable a third party to share your third-party account credentials with Amplify, we may obtain personal information via that mechanism. You may configure your accounts on these third-party platform services to control what information they share.
8. Security
Amplify maintains a comprehensive information security program and uses industry standard administrative, technical, operational, and physical measures to safeguard Student Data in its possession against loss, theft and unauthorized use, disclosure, or modification. Amplify performs periodic risk assessments of its information security program and prioritizes the remediation of identified security vulnerabilities. Please see https://amplify.com/security for a detailed description of Amplify’s security program.
In the event Amplify discovers or is notified that Student Data within our possession or control was disclosed to, or acquired by, an unauthorized party, we will investigate the incident, take steps to mitigate the potential impact, and notify the School in accordance with Applicable Laws.
Non-Student Data
Outside of Student Data, Amplify uses commercially reasonable administrative, technical, personnel, and physical measures to safeguard personal information in its possession against loss, theft, and unauthorized use, disclosure or modification.
9. Data Storage and Transfers
We are a United States Company, and our servers are hosted, managed, and controlled by us in the United States. If you are outside of the United States, we use industry standards to protect your data when it leaves your country of residence and your data will always be protected in accordance with this Privacy Policy, Applicable Laws and our Agreement regardless of the storage location.
Additionally, where we transfer your personal information to service providers outside of the United Kingdom (UK), European Economic Area (EEA), or other region that offers similar protections, we use specific appropriate safeguards to contractually obligate such service providers to protect personal information in accordance with Amplify’s commitment to privacy and security and applicable data protection laws.
If you have questions or wish to obtain more information about the international transfer of your personal information or the implemented safeguards, please contact us using the contact information below.
10. Data Retention / Deletion
Student Data
Upon request, we provide the School the opportunity to review and delete the personal information collected from Students. We will retain Student Data for the period necessary to fulfill the purposes outlined in this Privacy Policy and our Agreement with the School. We do not knowingly retain Student Data beyond the time period required to support the School or Authorized School User’s educational purpose, unless authorized by the School or Authorized School User. Upon request, Amplify will return, delete, or destroy Student Data stored by Amplify in accordance with applicable law and customer requirements. We may not be able to delete all data in all circumstances, such as information retained in technical support records, customer service records, back-ups, and similar business records. All such information will be protected in accordance with this Privacy Policy and our Agreement until it has been permanently deleted. Unless otherwise notified by the School, we will delete or de-identify Student Data after termination of our Agreement with the School.
Non-Student Data
Outside of Student Data, we keep personal information as long as it is necessary or relevant for the practices described in this Privacy Policy or as otherwise required by our Agreement with the School, if applicable. We determine the appropriate retention period for personal information on the basis of the amount, nature and sensitivity of the personal information being processed, the potential risk of harm from unauthorized use or disclosure of the personal information, whether we can achieve the purposes of the processing through other means, and on the basis of applicable legal requirements (such as applicable statutes of limitations).
11. What rights and choices do you have?
What Choices Do You Have?
Marketing/Advertising
As noted above, we do not use Student Data for marketing purposes and we do not direct marketing to Students. Amplify does not use third party cookies and similar technologies for advertising and marketing purposes on Student-facing portions of the Products. The choices below apply to Non-Student Authorized Users.
Opt-out of Marketing Communications. If you want to stop receiving promotional materials from Amplify, you can follow the unsubscribe instructions at the bottom of each email or email us at privacy@amplify.com. Amplify does not send marketing communications to Students.
Opt-out of Cookies and Similar Tracking Technologies. With respect to cookies, you may be able to reject cookies through your browser or device controls. Note that you have to opt-out of cookies on each browser or device that you use. If you replace, change, or upgrade your browser or device, or delete your cookies, you may need to use these opt-out tools again. Please be aware that disabling cookies may negatively impact your experience as some features may not work properly. To learn more about browser cookies, including how to manage or delete them, check the “Help,” “Tools,” or similar section of your browser.
What Rights Do You Have?
Individuals in the U.S.
- What Rights Do You Have With Respect to Student Data?
- Review and Correction. FERPA requires schools to provide parents with access to their children’s education records, and parents may request that the school correct records that they believe to be inaccurate or misleading.
- If you are a parent or guardian and would like to review, correct, or update your child’s data stored in our Products, contact your School. Amplify will work with your School to enable your access to and, if applicable, correction of your child’s education records.
- If you have any questions about whom to contact or other questions about your child’s data, you may contact us using the information provided below.
- Other Privacy Rights? Please see section 3 of our supplemental disclosures: “Additional U.S. State Privacy Law Rights” for more information about your U.S. privacy rights
Individuals in the EU/UK
Please see section 4 of our supplemental disclosures: “Notice for European Economic Area and United Kingdom Customers” for more information about your EU/UK privacy rights.
12. COPPA
We do not knowingly collect personal information from a Child User unless and until a School or Educator, with the permission of the School, has authorized us to collect such information to provide the Products. Amplify relies on the School acknowledging that it is acting as the parent’s agent and consenting on the parent’s behalf to process personal information of Child Users in accordance with all applicable provisions of COPPA. To the extent COPPA applies to the information we collect, we process such information for educational purposes only, and no other commercial purpose, at the direction of the School and on the basis of the School’s authorization. If you are a parent or guardian and have questions about your child’s use of the Products and any personal information collected, please direct these questions to your child’s school.
Please refer to the Appendix–Supplemental Disclosures if you are a Home User.
13. Updates to this Privacy Policy
We may change this Privacy Policy in the future. For example, we may update it to comply with new laws or regulations, to conform to industry best practices, or to reflect changes in our product offerings. When these changes do not reflect material changes in our practices with respect to use and/or disclosure of Authorized Users’ personal information, including Student Data, such changes to the Privacy Policy will become effective when we post the revised Privacy Policy on our website. In the event there are material changes in our practices that would result in Authorized Users’ personal information being used in a materially different manner than was disclosed when the information was collected, with respect to Student Data, we will notify the School, and with respect to other information, we will notify you via email and provide an opportunity to opt out before such changes take effect.
14. Contact us
If you have questions about this Privacy Policy, please contact us at:
Email: privacy@amplify.com
Mail: Amplify Education, Inc.
55 Washington St.#800
Brooklyn, NY, 11201
Phone: (800) 823-1969
Attn: General Counsel
To report a security vulnerability, visit https://amplify.com/report-a-vulnerability/.
Appendix – Supplemental Disclosures
1. Mathigon and Amplify Classroom accounts
While our Products are geared towards Schools we do provide a limited opportunity for Home Users to use the Products at home—outside of the school context. We do not allow persons under the age of 13 (or those under the age of consent in any applicable jurisdiction) to register for an account with us outside the school context.
If you are a Home User, you are prohibited from collecting or providing any personal information from students or minors. You are permitted to access the platform for instructional purposes, but you may not enroll or roster minors, create accounts for minors, or input any personal information of minors into the Product.
Please note that most parts of Mathigon can be used without creating an account or providing any personal information that directly identifies you.
What Rights Do You Have? If you are a Child User who is 13 or older with a legacy Mathigon account (or the parent or guardian of a Child User with a legacy Mathigon account), you may request that we provide for your review, delete from our records, or cease collecting any Child User personal information. To the extent that you are unable to exercise these rights through self-service features within your account with us, please contact us by sending an email to: help@amplify.com and we will provide assistance.
2. U.S. Notice at Collection
| Personal Information We Collect | How We Use Personal Information |
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Student Data, which includes:
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Authorized Users, which includes:
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Some of the information described above may be considered “sensitive” under the laws of certain jurisdictions (i.e., account credentials and race/national origin) (“Sensitive Information”). We use Sensitive Information for necessary or reasonably expected purposes – specifically, to provide you with our Services (i.e., account credentials are used to allow account logins and race/national origin are used for the School’s reporting purposes when voluntarily provided by the School).
We do not sell or share your personal information, as described in California law.
We retain your personal information for as long as reasonably necessary for the purposes disclosed in the chart above. Additional information about our retention of Student Data and personal information from other Authorized Users can be found in Section 10 of this Privacy Policy.
Please see the Additional U.S. State Privacy Law Rights section of this appendix for information about your privacy rights pursuant to applicable U.S. law.
Notice of Financial Incentive
From time to time, to support our services, we offer opportunities to complete surveys and questionnaires. As an incentive for completing the survey or questionnaire, you can voluntarily provide personal information as an entry into a raffle drawing or to obtain other benefits, discounts, offers, or deals that may constitute a financial incentive under California law (“Financial Incentive”). The categories of personal information required for us to provide the Financial Incentives include: contact information and any other information that you choose to provide when you complete the survey.
Participation is voluntary and you can opt out at any time before the survey is complete. We do not allow students to participate in our surveys.
The value of the personal information we collect in connection with our Financial Incentives is equivalent to the value of the benefit offered.
3. Additional U.S. State Privacy Law Rights
Note for Requests Relating to Student Data: Because Amplify provides the Products to Schools as a “School Official,” we collect, retain, use, and disclose Student Data only for or on behalf of the School for educational purposes, including the purpose of providing the Products specified in our Agreement with the School and for no other commercial purpose. Accordingly, we act as a “service provider” for the School with respect to School Data. We work with the School to support and assist them in addressing privacy requests relating to School Data. Please reach out to your School directly if you wish to exercise any privacy rights that may be available to you.
For all other requests: With respect to Amplify Data, individuals residing in certain U.S. states have the following rights, regarding your personal information (each of which is subject to various exceptions and limitations):
- Access. You have the right to request, up to two times every 12 months, that we disclose to you the categories of personal information collected about you; the categories of sources from which the personal information is collected; the categories of personal information sold or shared; the business or commercial purpose for collecting, selling, or sharing the personal information; the categories of third parties with whom personal information was shared; and the specific pieces of personal information collected about you.
- Correction. You have the right to request that we correct inaccurate personal information collected from you.
- Deletion. You have the right to request that we delete the personal information that we maintain about you. Even after the deletion of your account, some personal information may remain on our servers, such as in technical support logs, server caches, data backups, or email conversations. These will be automatically deleted after a reasonable amount of time, unless we are legally required to retain information for longer, or unless there is a legitimate business reason (e.g. security and fraud prevention or financial record-keeping). We are not required to delete any information which has been aggregated or de-identified in accordance with Section 5.
- No Discrimination. You have the right not to be discriminated against for exercising these rights.
- Appeals. You have a right to appeal decisions concerning your ability to exercise your consumer rights.
See Submitting Requests section below for details on submitting a request to exercise these rights.
4. Notice for European Economic Area (EEA) and United Kingdom (UK) Customers
As detailed at the beginning of our Privacy Policy (under the section titled “Our Role”), Amplify operates primarily as a processor that collects personal information on behalf of the School, and we act as a controller in limited circumstances where we offer Products outside the school context.
If you represent a School in the EEA or the UK, please note that we process personal information in accordance with this Privacy Policy, our Acceptable Use Policy, and our standard Data Protection Agreement, which sets out our responsibilities when it comes to our processing activities. Schools must send an email to privacy@amplify.com to enter into that DPA.
Lawful Basis for Processing
We rely on the following lawful bases for our processing activities:
- Consent;
- We obtain your consent to use cookies to collect and process device and usage data to understand how individuals use our Products.
- Pursuant to a contract for use of our Products;
- We process School Data to provide our Products (e.g., to create, authenticate and manage your account, to verify your identity, to manage our Products) pursuant to the Agreement between us and the School, as required in order for us to perform our obligations.
- To comply with our legal obligations;
- We process all categories of personal information that we collect to ensure the safety and security of our Products where we are complying with security requirements under data protection and cyber and information security law.
- We process all categories of personal information that we collect to comply with our legal obligations which includes, for example, to access, retain or share certain personal information where we receive a valid request from a government body, law enforcement body, judicial body regulator or similar, to deal with legal claims and prospective legal claims, and to ensure we are complying with applicable laws.
- When we have a legitimate interest in doing so, which is not outweighed by the risks to the individual.
- We process all categories of personal information that we collect to support the provision, effective management, and improvement of our Products where such activities are not strictly required under our contract. This is in our legitimate interests to ensure that we are providing the best possible service.
- We process all categories of personal information that we collect to ensure the safety and security of our services where this is important but not required under the data protection law or cyber and information security laws. This is in our legitimate interests to ensure the security of our services and systems, to prevent threats, abuse or fraudulent or unlawful activity, to promote safety and security and to ensure our Products are used in accordance with our terms and conditions.
- We process the contact information of Non-Student Authorized Users to manage our relationship, including to respond to queries or otherwise communicate with you in relation to our Products and the operation of our business where this is not strictly required under a contract with you. This is in our legitimate interests to communicate with and resolve queries from users of our Products and to ensure that we are providing the best possible service.
We process the contact information and survey data of Non-Student Authorized Users for internal research and marketing purposes in limited circumstances (e.g. to periodically send newsletters and other promotional materials), which will not be based on Student Data or directed to Students. This is in our legitimate interests to understand our customers and prospective customers, understand how our products and services are perceived in the market, to promote our products, and to grow and develop our business.
Your Data Subject Rights
Note for Requests Relating to School Data: Amplify acts as processor to its School customers with respect to all School Data. We work with our School customers to support and assist them in addressing privacy requests relating to School Data. Please reach out to your School directly if you wish to exercise any privacy rights that may be available to you.
For all other Requests – With respect to Amplify Data, you have the following rights if you are in the EEA or UK, subject to certain exceptions:
- Right of access: You have the right to ask us for confirmation on whether we are processing your personal information and access to that personal information.
- Right to correction: You have the right to have your personal information corrected.
- Right to erasure: You have the right to ask us to delete your personal information.
- Right to withdraw consent: You have the right to withdraw consent that you have provided.
- Right to lodge a complaint with a supervisory authority: You have the right to lodge a complaint with a supervisory authority.
- Right to restriction of processing: You have the right to request the limiting of our processing under limited circumstances.
- Right to data portability: You have the right to receive the personal information that you have provided to us, in a structured, commonly used, and machine-readable format, and you have the right to transmit that information to another controller, including to have it transmitted directly, where technically feasible.
- Right to object: You have the right to object to our processing of your personal information
See Submitting Requests section below for details on submitting a request to exercise these rights.
5. Submitting Requests
To exercise any of the rights described in sections 2 and 3 of this appendix, email us at privacy@amplify.com and specify which privacy right you intend to exercise. We may require additional information from you to allow us to confirm your identity. The verification steps will vary depending on the sensitivity of the personal information and whether you have an account with us. Please note that your rights may not apply in all cases. For example, we may need to retain your personal information to comply with our legal obligations, resolve disputes, prevent fraud and enforce our agreements. We will inform you if we are not able to fully respond to your requests. You may designate an authorized agent to make a request on your behalf. When submitting the request, please ensure the authorized agent identifies himself/herself/itself as an authorized agent and can show written permission from you to represent you. We may contact you directly to confirm that you have authorized the agent to act on your behalf or confirm your identity.
Complaints
If you have any issues, you have the right to lodge a complaint with an EEA or UK supervisory authority. We would, however, appreciate the opportunity to address your concerns before you approach a data protection regulator and would welcome you directing an inquiry first to us. To do so, please contact us by email at privacy@amplify.com or by mail at Amplify Education, Inc., 55 Washington St.#800, Brooklyn, NY, 11201.
6. Google APIs
Amplify uses Google’s Application Programming Interface (API) Services to enable Authorized Users to log in to Amplify, import classes and rosters from Google Classroom, create assignments in Google Classroom, and copy, edit, and publish Amplify content using Google Slides. Amplify will use and transfer information received from Google’s API in accordance with Google API Service User Data Policy, including the Limited Use requirements.
Update History:
Update: 6/13/2025: This Policy has been updated to align with product updates and to provide additional context for authorized educational use of Amplify’s Products.
Update 6/27/2024: The Policy has been updated to include an explanation regarding Google APIs in the Appendix — Supplemental Disclosures section.
Update 6/30/2023: This Privacy Policy has been updated to address new state law data privacy requirements.
Website Privacy Policy
Last Modified: February 2026
Update: February 2, 2026: This Privacy Policy has been updated to address additional rights for individuals in the European Union/UK.
Below is the Website Privacy Policy for the amplify.com site (“Privacy Policy”). For purposes of clarity and as further outlined below, this Privacy Policy does not apply to student data. You can visit this page to read about the principles and policy governing student data collected and maintained on behalf of our school customers.
We advise you to read this Privacy Policy in its entirety, including the jurisdiction-specific provisions in the appendix. Our Notice at Collection for California Residents is available in the Notice for our California Customers.
Who We Are / What This Privacy Policy Covers
Amplify Education, Inc. (“Amplify”) recognizes the importance of protecting the privacy and security of your personal information. This Privacy Policy describes our practices in connection with information that we may collect through your use of this website (the “Site”).
This Privacy Policy does not apply to Amplify’s handling of:
- student data or other information collected from users of Amplify’s products that support classroom instruction and learning, which are governed by our Customer Privacy Policy.
- staff or applicant data that we process in accordance with our staff or applicant privacy notice, respectively.
If you have any question as to what legal agreement or privacy policy controls the collection and use of your information, please contact us using information below in the Contact Us section.
This Privacy Policy is incorporated into and is subject to our Website Terms of Use, which governs your use of the Site.
Our Role: We are the controller of all personal information (as defined below) that we receive through our Site and can be reached by email at privacy@amplify.com or by mail at Amplify Education, Inc., 55 Washington St.#800, Brooklyn, NY, 11201.
1. What personal information do we collect?
When you visit and / or interact with our Site, we may collect the following information about you that, alone or in combination, could be used to identify you or your device (“personal information”):
- Contact Information, such as name, district / school name, professional affiliation, title / role, email address, shipping address, address and phone number.
- Account Information, such as customer user login and password.
- Demographic Information, such as age and gender.
- Information You Submit, such as information voluntarily provided on message boards, feedback sections, and other public areas of the Site.
- Site Activity Information, which is collected when you access and interact with the Site, we and our Service Providers (as defined below) may collect certain information about those visits. For example, we or our Service Providers may receive and record information about your computer and browser, including your IP address, browser type, and other software or hardware information. If you access the Site from a mobile or other device, we may collect a unique device identifier assigned to that device, or other characteristics of the device hardware, operating system and configurations for that device. On certain pages of the Site, we may use third party tools to help us look at mouse movements, clicks, keystrokes, data or text entered, and the pages you visit.
- Location Information, such as state, country and / or zip code, which we use to help us customize your experience, as well as to help us facilitate your privacy rights.
- Audio, electronic, visual, or similar information: such as customer service interactions, call recordings, chat transcripts, files you attach, and email, text, or other correspondence.
If you make a purchase through our online store, you may provide payment and other information directly to our third party e-commerce platform to complete your purchase.
We ask that you not send us, and you not disclose, any government identifiers (such as social security numbers) or information related to racial or ethnic origin, health, or criminal background on or through the Site or otherwise.
2. Where/How do we collect personal information?
Amplify may collect personal information directly from you at various points, including the following:
- Product Information and Newsletters. When you submit a request to obtain information about our products, services or other informational material or subscribe to one of our newsletters, you may be asked to submit information such as name, professional affiliation, email address, company name, address and phone and details on your query or interests in our products and services. This information is collected to help us process your request.
- Customer Support. When you submit a form to contact our customer service, you may be asked to submit information such as name, e-mail, district, customer user login and password and details on your query. In addition, some features of our Site, such as our customer live chat functionality or other customer service systems may allow you to voluntarily provide personal information to us. This information is collected to help us process your request. Please only provide what is needed to facilitate the support request.
- Product Orders. If you use e-commerce areas of our Site to order our products, we request information from you on our order form. To purchase products through the Site, you must provide contact information (such as name and shipping address) and financial information (such as credit card number). This information is used for billing purposes and to fill your orders. We will also use this information to contact you to confirm your order or to inform you of any issues or delays.
- Registration. You may be asked to submit information to use certain parts of the Site (such as posting comments on certain areas of the Site), register for an event or webinar, or view restricted content that may be available on the Site. For instance, you may be asked to provide your name, email address and event or webinar-related preferences to help us process your registration or content request.
- Public Areas and Discussion Forums. Any information you share in public areas, such as message boards or feedback sections, becomes public. Please be careful about what you disclose and do not post any personal information that you expect to keep private.
- Contests and Sweepstakes. When we run a contest or sweepstakes relating to the Site or Amplify, it will be accompanied by a set of rules. The rules for each contest/sweepstakes will specify how the information gathered from you for your entry will be used and disclosed.
As you visit or use our Site, we may collect Site activity information through cookies and similar technologies.
- Cookies, Pixels, and Other Tracking Technologies. Cookies and other tracking technologies (such as pixels, beacons, and Adobe Flash technology) are small data files that are placed on your computer or mobile device when you visit a website. They allow the website or mobile app to remember your actions and preferences over a period of time. We use the following types of cookies:
- Strictly necessary cookies – These are cookies that are required for the operation of our Site. They include, for example, cookies that enable you to log into secure areas of our Site. These cookies are not generally stored beyond the browser session and are less likely to include personal information. This category of cookies cannot be disabled.
- Functionality Cookies – We use these cookies so that we recognize you on our Site and remember your previously selected preferences. These cookies are stored on your device between browsing sessions but expire after a pre-defined period. These cookies enable our Site to “recognize” you when you use our Site, including your preferences such as your preferred language , time, and location. A mix of first party (placed by us) and third-party cookies (placed by third parties) are used.
- Analytics Cookies – These cookies help us and our Service Providers compile statistics and analytics about users of the Site, including Site Activity Information. For example, we use Google Analytics to help us understand how users interact with the Platform. Google Analytics uses cookies to track your interactions with the Site, then collects that information and reports it to us. This information helps us improve the Site so that we can better serve you. To learn more about Google Analytics, visit https://support.google.com/analytics/answer/6004245?hl=en. If you wish, you can opt-out of Google Analytics by installing the Google Analytics Opt-out Browser Add-on, available on https://tools.google.com/dlpage/gaoptout.
- Advertising Cookies – We use these cookies to collect information about your visit to our Site, the content you viewed, the links you followed and information about your browser, device, and your IP address. We sometimes share some limited aspects of this data with third parties for advertising purposes. We may also share Site Activity Information collected through cookies with our advertising partners. This means that when you visit another website, you may be shown advertising based on your browsing patterns on our Site.
For information on how to opt-out of these technologies, please see What Choices Do You Have? below.
- Social Plugins. Certain areas of our Site permit you to utilize social media functionality, such as the Facebook “Like” or Google “+1” buttons (“Social Plugins”). To use a Social Plugin, you must authorize the third-party provider of that Social Plugin, e.g. Facebook or Google, to access, collect, and/or disclose your information related to your use of that Social Plugin, subject to that company’s privacy policies, which may differ from this Privacy Policy. In addition, such providers may be able to collect information about you, including your activity on the Site, and they may notify your connections on their social networking platform about your use of the Site. Such services may also employ unique identifiers that allow your activity to be monitored across multiple websites for purposes of delivering more targeted advertising to you.
Amplify also receives information from other sources.
- Information from Other Sources. We may supplement any information we collect via this Site with information from publicly or commercially available sources.
3. How do we use personal information?
We may use any personal information and other information we collect from and about you for the following purposes and as described elsewhere in this Privacy Policy:
- To provide and manage the Site. We use the personal information we collect from and about you to provide the Site and features to you, including to measure and improve its services and features, to personalize your experience by delivering relevant content, to deliver marketing messages, to allow you to comment on content, to provide you with customer support, and to respond to inquiries. We may also use and disclose aggregate or anonymous data about your use of and activity on the Site to assist us in this regard and for any other purpose.
- To contact you. Amplify may periodically send promotional materials (e.g., newsletters) or notifications related to the Site and to Amplify’s business to the contact information you provided to us at registration.
- To improve our products and services. We may use your personal information for our business purposes, such as data analysis, audits, developing new products and services, enhancing the Site, improving our services, identifying usage trends, and determining the effectiveness of our promotional campaigns.
- For marketing and advertising. We may use your personal information to help us market our products to you or your school district.
4. To whom do we disclose personal information?
We may disclose any personal information and other information we collect from and about you for the following purposes and as described elsewhere in this Privacy Policy:
- To share with our affiliated education companies. Amplify may share your personal information with Amplify’s affiliated education companies for the purposes described in this Privacy Policy.
- To allow service providers to assist us. We may engage third party service providers, agents and partners (“Service Providers”) to perform functions on our behalf, such as analytics, credit card processing, shipping or stocking orders and providing customer service. We may disclose your personal information to such Service Providers to enable them to assist us in these efforts.
- To allow our marketing and advertising partners to assist us. We may engage marketing and advertising partners to help us market and advertise our products and services, including via digital ads sent in connection with your visit to the Site. We may disclose Site Activity information, as well as contact information and other aggregate insights to such partners to enable them to assist us in these efforts.
- To protect the rights of Amplify and our users. There may be instances when Amplify may disclose your personal information, in situations where Amplify has a good faith belief that such disclosure is necessary or appropriate in order to: (i) protect, enforce, or defend the legal rights, privacy, safety, operations, or property of Amplify, our parents, subsidiaries or affiliates or our or their employees, agents and contractors (including enforcement of our agreements, including our terms of use); (ii) protect the rights, safety, privacy, security or property of users of the Site or others; (iii) protect against fraud or for risk management purposes; (iv) comply with the law or legal process, including laws outside your country of residence; (v) respond to requests from public and government authorities, including those outside your country of residence; or (vi) allow us to pursue available remedies or limit the damages that we may sustain.
- To complete a merger or sale of assets. If Amplify sells all or part of its business or makes a sale or transfer of its assets or is otherwise involved in a merger, transfer or other disposition of all or part of its business, assets or stock (including in connection with any bankruptcy or similar proceedings), Amplify may transfer your personal information to the party or parties involved in the transaction.
5. What rights and choices do you have?
Opt-out of Marketing Communications. If you want to stop receiving promotional materials from Amplify, you can follow the unsubscribe instructions at the bottom of each email. There are certain service notification emails that you may not opt-out of, such as notifications of changes to the Site or policies. If you have additional questions, please contact us using information below in the Contact Us section.
Opt-of Cookies and Similar Tracking Technologies. There are a few ways to opt out or delete cookies.
- On Your Browser. Most browsers are initially set to accept cookies, but your browser may permit you to change your settings to notify you of a cookie being set or updated, or to block cookies altogether. Please consult the “Help” section of your browser for more information. Please note that by blocking any or all cookies you may not have access to certain features, content or personalization that may be available through the Site. Please also note that you must opt out separately on each device (including each web browser on each device) that you use to access our Site if you wish to opt out, and if you clear your cookies or if you use a different browser or device, you will need to renew your opt-out preferences.
- Interest-Based Advertising. Some advertisers and marketing companies participate in the self-regulatory programs of the Digital Advertising Alliance (“DAA”) and European Interactive Digital Advertising Alliance (“eDAA”) in connection with online interest-based advertising. DAA and eDAA provide consumers with the ability to opt out of receiving interest-based advertising from their program participants at the following links:
What Rights Do You Have?
- Please see section 3 of our supplemental disclosures: “Additional U.S. State Privacy Law Rights” for information about your U.S. privacy rights
- Please see section 4 of our supplemental disclosures: “Notice for European Economic Area and United Kingdom Customers” for information about your EU/UK privacy rights.
6. Security
Amplify uses commercially reasonable administrative, technical, personnel and physical measures to safeguard personal information in its possession against loss, theft and unauthorized use, disclosure or modification.
7. Data retention / Deletion
We will retain your personal information for the period necessary to fulfill the purposes outlined in this Privacy Policy unless a longer retention period is required or allowed by law. Even after we have deleted your personal information from our systems, copies of some information from your account may remain viewable in some circumstances – where, for example, you have shared information with social media platforms and other unaffiliated services. We may also retain backup information related to your account on our servers for some time after cancellation for fraud detection or to comply with applicable law or our internal security policies. Because of the nature of caching technology, your account may not be instantly inaccessible to others, and there may be a delay in the removal of the content from elsewhere on the Internet and from search engines.
8. Data Storage and Transfers
We are a United States Company, and our servers are hosted, managed, and controlled by us in the United States. If you are outside of the United States, we use industry standards to protect your data when it leaves your country of residence and your data will always be protected in accordance with this Privacy Policy, Applicable Laws and our Agreement regardless of the storage location.
Additionally, where we transfer your personal information to service providers outside of the United Kingdom (UK), European Economic Area (EEA), or other region that offers similar protections, we use specific appropriate safeguards to contractually obligate such service providers to protect personal information in accordance with Amplify’s commitment to privacy and security and applicable data protection laws.
If you have questions or wish to obtain more information about the international transfer of your personal information or the implemented safeguards, please contact us using the contact information below.
9. External third-party services
The Site may be linked to sites operated by unaffiliated companies, and may carry advertisements or offer content, functionality, games, newsletters, contests or sweepstakes, or applications developed and maintained by unaffiliated companies. Amplify is not responsible for the privacy practices of unaffiliated companies, and once you leave the Site via a link or enable an unaffiliated service, you are subject to the applicable privacy policy of the unaffiliated service.
10. Updates to this policy
Amplify may modify this Privacy Policy. Please look at the Last Revised Date at the top of this Privacy Policy to see when this Privacy Policy was last revised. Any changes to this Privacy Policy will become effective when we post the revised Privacy Policy on the Site. If you do not wish to be bound by the terms of the revised Privacy Policy, you must discontinue your use of the Site.
11. Contact us
If you have questions about this Privacy Policy, please contact us at:
Email: privacy@amplify.com
Mail: Amplify Education, Inc.
55 Washington St.#800
Brooklyn, NY, 11201
Phone: (800) 823-1969
Attn: General Counsel
Appendix – Supplemental Disclosures
1. Notice for our California Customers
We retain your personal information for as long as you are an active user of our Site or continue to have an account with us, and in accordance with our legal obligations (which may require us to hold information to provide financial and other reporting and to defend against potential claims). If you are a California resident, please see below for information about your rights pursuant to California law.
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S5-03. Cultivating a joy of learning with Sesame Workshop
Listen as we chat with Dr. Rosemarie Truglio, senior vice president of curriculum and content for Sesame Workshop! Continuing our theme of math anxiety this season, we sat down with Dr. Truglio to chat about Sesame Street and her thoughts on how to spread a growth mindset to young children and put them on course to academic achievement and long-term success.
Listen today and don’t forget to grab your MTL study guide to track your learning and make the most of this episode!
Dr. Rosemarie Truglio (00:00):
Children don’t come with this math anxiety. Math anxiety is learned.
Bethany Lockhart Johnson (00:07):
Welcome back to Math Teacher Lounge. I’m Bethany Lockhart Johnson.
Dan Meyer (00:11):
And I’m Dan Meyer.
Bethany Lockhart Johnson (00:12):
Hello, Dan Meyer.
Dan Meyer (00:14):
Great to see you, Bethany. We are on episode three. Can you believe it?
Bethany Lockhart Johnson (00:18):
So, I feel like we’ve just started scratching the surface about math anxiety. We’ve talked to two amazing researchers. We’ve talked about what math anxiety is, how it’s often screened for some of the causes, some of the consequences … I mean, we’ve had some good conversations. Dan, what do you think?
Dan Meyer (00:38):
Definitely, I think that the consequences have only grown more dire in my head. I’m not sure how you feel about the consequences. But, you know, it is enough for me that we ask students to take mathematics for much of their childhoods, to worry about their anxiety, taking that. But to hear about from these researchers about all the different things that correlate with math achievement and math anxiety—talking about future careers, certainly, but even some other, more serious lifelong concerns? That gives me a lot of motivation to continue this study of math anxiety here with you on the show.
Bethany Lockhart Johnson (01:14):
It is really widespread. It has a big impact, not only on students, but on parents, on educators. You know, it’s—
Dan Meyer (01:23):
Multi-generational.
Bethany Lockhart Johnson (01:25):
Yes. And you know, so often when folks think of math anxiety, what I hear them say is, “Oh, yeah, in high school is when math really ramps up. That’s when anxiety starts.” But we know that it starts in our youngest learners. And our research has already backed that up. We know it. I’ve seen it in my classroom. You may have seen it with some students you work with. And let me tell you, it starts young.
Dan Meyer (01:52):
It does start early. Right now, I have a son that’s just started kindergarten, and he seems relatively math-positive, but we’ve known from our interviews on this show and other kinds of experiences that oftentimes, that feeling —that math is for me, and I am for math, and we are all friends — can turn on a single moment. It seems like one teacher says a thing that changes a student’s perception of themselves as a mathematician or of math itself. So I keep waiting with bated breath, hoping not to find that one moment that changes our current open posture towards mathematics. So now it’s time to really dive into some strategies for combating math anxiety.
Bethany Lockhart Johnson (02:34):
To help us out, we’ve called on a pretty exciting guest. I am so excited, Dan Meyer! We are being joined by Dr. Rosemarie Truglio. She is Senior Vice President of Curriculum and Content at Sesame Workshop. Sesame Workshop! As in, “Tell me how to get to Sesame Street.” Dan, I have to tell you, I spent many, many hours of my childhood watching Sesame Street. I have to ask, do you have happy Sesame Street memories? Is this part of your formation, Dan Meyer?
Dan Meyer (03:08):
At this point? In my advancing years, and the brain cells that I have left, Sesame Street is really kind of just a vibe in my head. But that vibe is such a pleasant one. One in which like nothing bad could happen. One in which learning is common and normalized and fun. And you just kind of feel at home, constantly.
Bethany Lockhart Johnson (03:33):
I don’t know about the “just the vibe” part, because for me, it is visceral. I’m there. I am actually … I mean, I might still be there.
Dan Meyer (03:42):
You could reenact some of the skits?
Bethany Lockhart Johnson (03:44):
. You didn’t watch Sesame Street with your kiddos when they were younger?
Dan Meyer (03:49):
We watched a lot of Elmo. A lot of Elmo. Yeah.
Bethany Lockhart Johnson (03:52):
Next-generation Sesame Street. Well, I think it’s so perfect that we’re gonna be talking about what Sesame Workshop does to help combat math anxiety and create a positive connection and relationship with mathematics. So I’m really excited to hear what Dr. Truglio and her team have been working on. And here’s our conversation with Dr. Truglio.
Dan Meyer (04:15):
Welcome to the show, Dr. Truglio. It is an honor.
Dr. Rosemarie Truglio (04:18):
Great to be here. Thank you for inviting me.
Dan Meyer (04:20):
You are Senior Vice President of Curriculum and Content at Sesame Workshop, which definitely sounds like the coolest job in the world to both four-year-old me and also Now me. Would you just help us help us with some backstory of how you ended up here, and what you do at Sesame Workshop?
Dr. Rosemarie Truglio (04:38):
Sure. It is a pretty cool job. And I am very fortunate that I’ve been in this position for the past 26 years. So, I am a developmental psychologist, and my job is to help Sesame Workshop identify curriculum needs, so that we could address them in the content that we create on the show and across our various platforms. So, Sesame Street is currently in its 53rd season. And we just, wrapped production for the 54th season, which we’ll debut next fall. And Sesame Street began with an experiment: Can television actually teach children school readiness skills, to have them better prepared for school? Especially those children who did not have access to formal education during the preschool years? And it is what we call a whole-child curriculum, because we’re dealing with all of the school readiness needs. So that that includes the academic needs, their social-emotional needs, and their health needs, as well as what we call these cognitive processing skills—how children learn content. Right? So it’s not just content skills, but how you approach learning and how you actually learn content. So as a grad student, I was fortunate to work at the Center for Research on the Influences of Television on Children. Very special center. It was at the University of Kansas. And my advisors, developmental psychologists, they studied the effects of television on children, both the positive effects and the negative effects. And so part of their research was to actually look at the longterm educational effects of Sesame Street. So I was working with Sesame Street content as a grad student, and then came to New York City. My first job was Assistant Professor at Teachers College, Columbia University. And when this position became available, Director of Research at the time, it was called, I took that job. And so my job was to oversee both the curriculum and the implementation of the curriculum, as well as the research. Because what we know, our co-founder, Joan Ganz Cooney has always said, for Sesame Street to be a successful educational program, production has to work closely with early childhood educators. They are the ones who know the curriculum and, and develop the curriculum goals, as well as the developmental psychologists who actually study how children are paying attention to the content. But more importantly, what are they comprehending from the content? And we all have to work together. Because even though we are the experts, the real experts are the children themselves. So nothing is deemed final until we actually show the children and see what they are learning from the content that we are producing.
Dan Meyer (07:54):
Are you referring to like, test audiences of kids then?
Dr. Rosemarie Truglio (07:57):
Yeah, I guess you could call it test audiences. I mean, I don’t. I don’t like to call it that because I see them as co-collaborators. I don’t see them as a test audience. Because, as I said, they’re the experts. It’s a collaboration. I mean, they’re the experts. And so I wanna know—
Dan Meyer (08:12):
As collaborators. I got it now. Yeah.
Dr. Rosemarie Truglio (08:14):
They help us. So that’s exactly what we tell the children too. So it’s called formative research. You know, we, we do what we call, um, storybook testing, an animated version of a storybook to have some little movement and see are they finding the story engaging, but more importantly, are they picking up on the intended educational lesson that we’re trying to teach in the story. So they are co-collaborators. they’re the ones who are helping us get the story just right for them.
Dan Meyer (08:46):
That’s really exciting, and makes me think about what classes might be like if students were regarded in that kind of lens as well. I just wanna say that my four-year-old self is on this interview as well, and is re-contextualizing all the stuff I saw as a kid. And it just felt like, at the time, you folks turned the camera on and went down to the street and we just had this real natural time. And it’s great to hear about all the intense preparation and co-construction at work and work that went into that time. Yeah,
Dr. Rosemarie Truglio (09:12):
It’s about a year preparation from start to finish. From the start of identifying, “What is the educational need? Is it an academic need? Is it a social-emotional need? Is it a health need? Is it a cognitive-processing need?” And then once we have the need identified, we have what we call a curriculum seminar. We bring in the experts who are studying this topic with preschoolers, because we wanna get it, we wanna get it right.
Bethany Lockhart Johnson (09:41):
Which, by the way, little behind the scenes: How often do you get to go to set?
Dr. Rosemarie Truglio (09:46):
So we’re in a production probably about six weeks out of the year. Covid really messed things up. ‘Cause we have to be really—we have very strict Covid protocols, but there is someone on my team—and sometimes we have to, you know, rotate for availability—but there’s always an educator on set.
Bethany Lockhart Johnson (10:06):
Awesome.
Dr. Rosemarie Truglio (10:07):
Because even though you stick to the script, questions arise; they wanna make changes; sometimes they have to cut; things are running too long and they have to cut and we gotta figure out where to cut. So there’s always an educator on set.
Bethany Lockhart Johnson (10:19):
But sometimes you go and have lunch, like—.
Dr. Rosemarie Truglio (10:21):
Oh, I go, yes. Sometimes I go—
Bethany Lockhart Johnson (10:23):
And just hang out with Big Bird, right?
Dr. Rosemarie Truglio (10:24):
Sometimes I go hang out with Big Bird. No, those are my friends!
Bethany Lockhart Johnson (10:27):
They are!
Dr. Rosemarie Truglio (10:28):
No, no, I go hang out with them. They’re my friends. Yes.
Bethany Lockhart Johnson (10:32):
When I think about Sesame Street and I think about … like, I can’t help but smile. Because I think I have such fond memories of the characters. I mean, we invited them, my mom invited them, into our home, right? And, you know, now I have a two-year-old and there’s no doubt that I’m gonna introduce him to Sesame Street. And I see how it really does feel like the folks who are doing this work, you and your team, you have a deep respect for children. So it makes sense that you call your test collaborators “collaborators,” right? They’re a part of it. And you know, I love that. And Sesame Street makes me smile. However, I’m like, we’re talking about math anxiety. And it’s so interesting, because as Dan and I were talking about our memories of Sesame Street … you know, it’s like Sesame Street feels like there’s not much anxiety. I mean, there are problems, and there’s problem solving, and it’s not like everything is perfect. But we figure it out. And it’s OK to make mistakes and it’s OK to try again. And a lot of times, we don’t see that in the math classroom—or at least, how folks talk about math. So, how do you all think about anxiety, about how to prevent it? Like, when you’re doing your work, you know that math anxiety is a real thing. But then that’s not translated in these experiences and the relationships with math that you’re building with your viewers.
Dr. Rosemarie Truglio (12:07):
Yeah, that’s a really good question, because it’s really easy, because our core audience are two- to four-year-olds and they love math. And what’s not to love, right? Because they are figuring the world out as they’re exploring the world. So you said something really interesting, that when you turn on the TV—when you turned on the TV when you were a child, and now you’re a mom of a two-year-old, we wanna make sure that the show represents content that is relevant and meaningful to our target audience. And that comes through with the characters. So all of our characters have very specific personalities, as all children do. And our characters represent all children, in terms of not only personality, but interest and learning styles, ’cause we wanna see—we wanna make sure that children see themselves in these characters. And we have a character who actually loves math. And he’s The Count.
Bethany Lockhart Johnson (13:12):
I’m like, “I know! I know who it is!” I will save you my impression. Although I have done it for my child. But I’ll save our listeners .
Dr. Rosemarie Truglio (13:20):
And you know, he’s an adult character. Some of our characters are preschoolers, like Elmo and Abby—they’re preschoolers—and Zoe. But The Count is an adult. He lives in the castle and he just loves numbers. But what’s really important is while we have The Count to explain—not explain to, but to portray to children, cause we don’t explain anything; we show children that math is more than number, right? Math is a pretty wide concept. Which is what I love about math. And the other thing about math is math language. The language of math. ‘Cause when we’re teaching children vocabulary words, we’re also teaching children the concept. Be it a math concept or a science concept or a social-emotional concept. So children don’t come with this math anxiety. Math anxiety is learned and it’s unfortunate. It’s picked up by their observations of the adults in their lives, who sometimes say out loud, “I don’t like math,” or “Math is hard,” or even worse, “I’m not good at math.” Or may even label it as math anxiety. That word won’t mean anything to a young child. But it then provides a, whaddya call it, like a negative valence for something that they never felt negative about. Because as they’re growing and interacting with the world, math is all around them. And there’s that sense of awe and wonder and joy, especially as they’re learning and they’re figuring it out. So I think we have to reframe math. Instead of saying “math anxiety,” we have to talk about the joy of math and all the wonderful joys that come with the exploration of these math concepts. Number is great. We know kids love numbers. We know that they love to count and use a big word here: enumerate . Because so many parents don’t make this distinction. They’ll say, “Oh, my child is counting!” Well, there’s rote counting, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, which is important. But then it’s like there’s an item for each number. So it’s one Cheerio, two Cheerios. And then as you point to each number, you are then figuring out what the set is, of the number of objects that you have. And then you get at what I love to call the meaningfulness of math. Right? Number has meaning. And as I said, it’s all part of your everyday activities. It’s part of—it’s in your kitchen; you’re following recipes; you’re measuring; you’re weighing. It’s at bath time, right? You could have the sorting of nested cups and you could, you know, and once again, the math language: big, bigger, biggest. These are relational concepts. You could then count what sinks and what floats, if you’re doing science. And then you could put them in two different buckets, and count. These are the items that sunk and these are the items that float. So math and bath time could be a lot of fun. And then there’s math and music. Music is so rich with math, as you talk about rhythm and tempo and dynamics and pitch and duration. That’s all math.
Bethany Lockhart Johnson (16:57):
The way that you talk about it, it is so rich, right? It is so multi-layered. And you know, I’ve shared on the podcast before: I’ve actually had parents in parent-teacher conferences say that, “Well, I wasn’t good at math either,” or “Math’s really not my thing.” And it’s really—it is, it’s rooted in that fear. And so I do see the way that you’re talking about it; I see that come through in Sesame Street. That, in a lot of ways, it’s reeducating parents, right? Because we hope that our caregivers are sitting next to their kiddo and enjoying it together and having conversations about it later. And there’s a way that parents then are also getting their own sense of what math can be, expanded. And I think there’s such a beauty in that. And I love the way that you talk about that, that you really are looking at, “Well, we wanna celebrate counting and the joyfulness of that. And let’s use math talk, you know, and let’s use these words and try out these ideas.” And it’s not because you’re trying to check some list. But you’re really exploring it and having fun together.
Dr. Rosemarie Truglio (18:03):
And you’re embracing it. And you mentioned the word “mistake.” So often when it comes to math, if you make a mistake—you make a mistake in counting or, you know, we’re not doing a lot of math equations on Sesame Street, but that’s when people feel like they can’t do math. ‘Cause they made a mistake. And that’s something that we are trying to address on Sesame Street, that it’s OK to make mistakes and you learn through mistakes. But you have to have—and I’m gonna come up with this other phrase now—you have to have what we call a growth mindset. What that means is that I may not be able to do this yet. Like, it’s called “the power of yet.” So we know that learning any concept, it takes time and practice. And how do we have children embrace the process, right? So often we focus on right and wrong. Now, there is right and wrong with math, of course. You know, there’s a right answer and there’s a wrong answer. But how do we focus, not on the end product, but the process through which you are engaging in? So let’s talk about measurement. Let’s talk about measuring the length and the width or the height of something. You might make some mistakes along the way, but you’re processing it. My son used to make all of these little structures for all his little play animals. Well, you know, he would measure and think he got it right. And then when he put the animals in, of course, you know, either the animal was too wide or it was too tall. And he would have to redo it. But you’re not redoing it from scratch, you’re redoing it now from experience. “I realize that if I’m gonna put the giraffe in with the elephant, I’m gonna need something wide as well as high.” Right? For the length, tall. And that’s process. And then, for children, when they figure it out, that “oops” and “aha”—the “aha” was like, “I did it!” And it’s so empowering, you know, giving them agency—not swooping in and saying, “All right, I’ll fix it for you. You know, we got the wide elephant and the tall giraffe and I’ll you know…”. NO! Having them do it. And another fun activity is in what we call informal measurement. And that’s like getting something of an equal size. It could be paper clips or it could be same-size blocks, and then measuring how long something is. So if it’s measured by blocks versus paperclips, you’re gonna have a lot more paperclips than you are blocks. And that kind of comparison is so fascinating for children. And so that’s measurement. And now we have counting. Like, how many paperclips long is something versus how many blocks long is something.
Dan Meyer (21:02):
So checking my understanding here, you’ve talked about how caregivers and other adults can transmit math anxiety by naming it and claiming it for themselves. And you’ve talked about, some really exciting ways that adults can involve students and kids in different kinds of math. I’d love to go upstream with you a little bit and wonder out loud, where does this anxiety come from initially? It’s gotta be more than adult one to kid two talking about anxiety, and transmitting it from human to human. What is the original spring from which all this anxiety flows?
Dr. Rosemarie Truglio (21:36):
Yeah. I do think it does—a lot of it does come from the adults in their lives. It’s unfortunate, because there is a lot of math talk about it, right? I can’t do math; I’m not good at math. Even when you’re at a restaurant and you get the bill and someone’s figuring out the tip, I can’t tell you how often it’s like, “Pass the bill, because I can’t do math.” Or if you actually then bring gender into it, you know, “Oh, girls aren’t good at math,” and that’s not true. There’s no evidence of that whatsoever, right? So in the younger grades, there’s no gender difference in terms of math ability. What’s also interesting about even socioeconomic status differences, you don’t see a lot of differences between low-income and middle-income children when it comes to math skills. Where you see differences is children’s ability to talk about their mathematical thinking. So if a child doing a math problem is asked, “How did you solve the problem?”, low-income children don’t often have the language to explain their thinking. So that’s something that we did on Sesame Street, where we focused a lot on what we call math talk. So, not just show number and show doing math, but actually narrate and giving the language. Because math literacy is one of the predictors of overall school achievement. So there’s that. They’re getting it from the adults in their lives. They’re getting it, unfortunately, sometimes from their teachers. But I think the anxiety comes from the fear of making mistakes. Because math, there is right and wrong, and always wanting to get the right answer. So that’s why this whole idea of reframing, and saying, “But really, it’s in the process.” So, you know, my son, math is not his strong suit. And I’ve been doing a lot of growth mindset with him as well. And there was a teacher that he had—I think in like 10th or 11th grade—who said, “In a test, I don’t wanna—I’m not even gonna look at the answer. I wanna see the process through which you GOT to this answer. And I’m going to grade the process. So the process could yield a right answer; it could yield a wrong answer. But you’re gonna get graded on the process. Because I wanna see how you are approaching the problem and how you’re thinking it through.” And I think that is a great example of, maybe, to try to reduce math anxiety. Because if you can get people excited about the process through which you’re learning—and that applies to all subjects, it’s not just math!
Bethany Lockhart Johnson (24:36):
I’m like, that applies to life! Right?
Dr. Rosemarie Truglio (24:38):
That applies to life!
Bethany Lockhart Johnson (24:39):
That’s so spot on. Wow. Yeah.
Dr. Rosemarie Truglio (24:41):
But I think that there’s so much focus on right and wrong, and not really understanding the value of the process. So on Sesame, we’ve been doing a lot of “oops” and “ahas.” You know, we’re gonna make mistakes, but what’s important is what do you DO when you make a mistake? So there’s a great episode with The Count. A couple of years ago. The Count was counting. Something he does every day. A lot of time, every day, ’cause he’s obsessed with counting and numbers. And he was counting an array of items.
Gladys the Cow (25:17):
I need 10 sandwiches all together.
The Count (25:22):
Well, of course.
Dr. Rosemarie Truglio (25:23):
And he made a mistake.
Elmo (25:25):
The Count?
The Count (25:25):
Hmm?
The Count (25:25):
Elmo thinks The Count made a little mistake.
The Count (25:31):
No mistake.
The Count (25:32):
Mm-hmm. Yeah.
Dr. Rosemarie Truglio (25:33):
And first time ever, did he make a mistake. And he fell apart.
The Count (25:38):
I must make sure that that never happens again. So I shall never count again.
Dr. Rosemarie Truglio (25:46):
And that’s an example of showing that, you know, you could get upset when you make a mistake, but what’s important is you gotta come back and you gotta come back to doing what you love. In his case, is counting and letting him know that it was an “oops.” But you learn that mistakes are OK. It’s OK to make a mistake and continue to do what you love.
The Count (26:13):
I must keep trying and you should, too.
Elmo (26:17):
Yeah!
The Count (26:17):
So come, let’s count the carrots together!
Elmo (26:18):
Oh, cool!
Bethany Lockhart Johnson (26:19):
And what a beautiful gift to show kiddos. Show that to kiddos, right? And to the adults. I wanna, you know, really acknowledge it, and say, “Hey look this, it’s OK.” And again, you’re giving them that language. That’s such a gift.
Dr. Rosemarie Truglio (26:34):
Thank you.
Dan Meyer (26:34):
We spend a lot of time wondering why other subjects don’t seem to suffer from this negative perception. And I think you’ve unlocked a lot of that. You’ve mentioned that there are issues that cut across different subject areas, but I think from my own experience and research and interviews, it seems that in ELA and the social sciences, there’s this aspect where you need to come up with a claim and “how are you seeing this?” And there are multiple defensible claims. And I love how you imported that generous pedagogy over into math with this example of a teacher who says, “You know what? It’s about the process here.” Disassociating answer and process.
Dr. Rosemarie Truglio (27:09):
And I think the other thing is like, when children are engaged in a project, for parents to point out: “You’re doing math!” Because they don’t realize that they’re doing math. Once again, math is so often equated solely with numbers and mathematical computations. So it was really interesting—the same is true for science. You know, when we’re talking to parents about the use of everyday—like, going to the supermarket or making dinner or bath time, there’s so much math and science in the everyday. And then when you point it out to them—”you’re doing math”—it’s like, “I’m doing math!” Like, you’re setting the table for a family of six: you’re doing math. That’s called one one-to-one correspondence. “I’m doing math: I’m setting the table.” Yeah, but you’re doing math. You can’t set the table because you have to know how many people are gonna be sitting at the table for dinner. You can’t follow a recipe without doing math. You can’t go shopping without doing math. There’s quantity; you gotta figure out how many peppers you gotta buy, or pounds. “I gotta get a bunch of potatoes and I gotta put ’em in the scale. And I have to get two pounds of potatoes.”
Bethany Lockhart Johnson (28:29):
So your book Ready for School: A Parent’s Guide to Playful Learning for Children Ages Two to Five. First, as a parent of a young toddler, I gotta say it’s such a tool; it’s such a resource. It’s very conversational. And I think about these ideas a lot, both in my work and, you know, just for fun. And yet, even if this wasn’t my chosen field, I still feel like it’s just so accessible. And I wanna flag something.
Dr. Rosemarie Truglio (29:01):
Thank you.
Bethany Lockhart Johnson (29:01):
Yeah, no. Thank YOU. . I wanna flag something that you said in the math chapter You were talking about the joy of math, and you said when it comes to our children, caregivers: “take pleasure in reading stories together, especially at bedtime, which in many households is a regular part of a child’s routine. But somehow the notion of introducing math concepts to our children seems daunting. In fact, some studies have shown that parents harbor a strong belief that while it’s important and pleasurable to support their child’s reading skills, it’s the responsibility of the schools to take care of teaching math.” And that quote, I highlighted it, I starred it! And I would love for you to say a little more about that, because you have given us already, like, a bounty of ideas that as caregivers we can do with our kiddos or the kiddos in our lives. And we’ve seen that even what they’re learning in school, it may not be the freeing, joyful math language that we hope our kiddos have access to.
Dr. Rosemarie Truglio (30:05):
Yeah, I’m glad you brought that up. Because a lot of our focus is on how children learn through playful experiences, and how they learn through play in particular. And there are so many playing, either a game or even playing ideas—like we talked about building, you know, a house for animals or building a fort. It’s just so filled with math. And I wish I could narrate for every young parent how I would hope that they would talk as they are co-engaged in this activity. And I think … we asked about, with the anxiety, the adults have to find the joy in math first. They have to see the math. That’s the problem. That’s why I hope that my book provides that. I want you to know that you are doing math and I want you to know that your child is what we call a mathematician—or in the science chapter, is a STEMist. Your child is already doing science, technology, engineering, and math. STEM is so integrated. So to acknowledge them—because babies are doing math! Babies know, they can distinguish between a small quantity and something that is a of a larger quantity and want the larger. Right? So, it’s natural for them. And they are taking it all in. I mean, the joy of watching a child just early counting: you know, one, two. And trying to then figure out the meaningfulness of two. It’s not three objects. There are actually two. And for a parent to see the joy in that I think is step one. And then to see the richness and how expansive math is, and that power of, oops, “I made a mistake, don’t freak out,” and then [not] say, “See, I’m not good at math,” but say, “Let me try again. I know I could figure this out.” Right? It’s all of that supportive language and supportive experiences that builds this mindset, a positive mindset. So that you hope that when you get into the higher grades, they’re not walking in and saying, “I can’t, I can’t do math.”
Dan Meyer (32:26):
Yeah. Super helpful. I think you point at one of the grownups—great powers in the world of kids, which is to label. To name things. And you know, you’ve talked about how grownups should ideally downplay some of their negative experiences with mathematics for the sake of the kid, but also to play up the positive stuff that they’re doing as mathematics. Like that right there, that’s math. I would love to know … you have an extremely loud megaphone to communicate messages about math and the world and everything through Sesame Street. One of the biggest that there is—and I just wonder if you could step out and imagine you had a magic wand to wave over the world in which students grow up, play and learn—what would you do like to help students have better associations or less math anxiety? And, you know, learn more about math itself?
Dr. Rosemarie Truglio (33:19):
If I had a magic wand, I would give everyone what we call a growth mindset that nothing is fixed and everything can be changed if you put the time and effort into the process, and enjoy the process. The joy of learning. I think, you know, it’s really sad. I don’t wanna be sad on your show. But when we were getting ready for the 50th anniversary, I was wondering, “What is gonna be the curriculum focus?” You know, we just came off of literacy and math literacy and social-emotional development. And we talked about the power of play. Playful learning. And building careers. Give children sophisticated play scenarios so that they could explore what they may wanna be when they grow up. Because there’s a concept: If I can see it, I can play it, I can be it. Right? So where are those portrayals? And it’s like, “What are we gonna do for the 50th?” And I had a convening of experts across all disciplines, and brought them into a room. And I said, you know, “What keeps you up at night? Like, what are you worried about?” Sort of like the State of the Union of Child Development. And this is where the sad part is. They talked about how that sense of joy, that sense of wonder, that sense of curiosity, that sense of flexible thinking and creative thinking, was disappearing in early childhood. Wow. If it’s disappearing in early childhood, we are in big, big trouble . ‘Cause I could see it disappearing later on, you know, as you advance in grade. But what do you mean, it’s disappearing in childhood? And then they talked about the fear of making mistakes. And that goes against—it’s the opposite of a growth mindset. And so we have to bring back that sense of joy, wonder, asking those why questions and embracing them. So it’s another problem parents have. They’re fine with the “why” questions until the “whys” become so difficult they don’t have the answers. And then they don’t want the “why” questions, because now they feel like they’re not smart enough to answer their child’s “why” questions. How do I flip that around to be much more positive and say, “You know, I don’t know! But let’s find out together. Let’s explore together; let’s experiment together.” That’s what I mean about the shift in the mindset, that growth mindset. We should not know all of the answers, but where’s the joy of, “Wow, I don’t know, let’s go find out together”? And that applies to math too. But you have to have that open mindset. You have to—you, as yourself, have to have that growth mindset.
Bethany Lockhart Johnson (36:20):
I love that magic wand. I want that magic wand! And I think what—like Dan said about this megaphone, this opportunity to reach so many young people, so many caregivers—what a gift! And I’m so grateful that you took time to be in the lounge with us, and that you have shared these ideas. Because truly, I think, like you said, it’s really our youngest learners, right? How can we create and cultivate these opportunities for our youngest learners to find the joy in mathematics and just in learning, right?
Dr. Rosemarie Truglio (36:54):
Yeah.
Bethany Lockhart Johnson (36:55):
So thank you. Thank you so much, Dr. Truglio. We are deeply grateful for your insight and for all the work you do. And we continue to invite the world of Sesame Street into our homes.
Dr. Rosemarie Truglio (37:08):
Thank you. Thank you for allowing us to come into your home, and for you to re-learn with your child as you’re watching Sesame Street. Because it’s very much a parenting show, as it is for a child-directed show, because we are blessed to have these wonderful human cast members who are the stand-ins for parents. And so we are often giving you the language for how to talk about and how to problem-solve together. So thank you.
Dan Meyer (37:43):
Thanks so much for listening to our conversation with Dr. Rosemarie Truglio, Senior Vice President of Curriculum and Content at Sesame Workshop.
Bethany Lockhart Johnson (37:51):
Dr. Truglio is also the author of Sesame Street Ready for School, A Parents Guide to Playful Learning for Children Ages Two to Five, and we’re gonna make sure we put a link to that in the show notes because it is really, really a rich resource. I’m diving in. I have so many ideas bookmarked that I wanna try out with my kiddo.
Dan Meyer (38:09):
Yeah, it’s really exciting to see—like, for a classroom educator, I just kinda assumed that a lot of math learning happens in the classroom context. That’s my lens. So yeah, I loved reading the book and seeing all the different opportunities for parents for just out there in the world, in front of your house, at the supermarket. All the different opportunities there are for mathematical thinking, and then to think about how to bring that into some of those routines and ideas into the classroom, into formal schooling.
Bethany Lockhart Johnson (38:35):
Exactly. Exactly. Like Dr. Truglio said, the caregivers’s disposition about mathematics matters so deeply. Your teachers’ dispositions about mathematics, their beliefs, the way that you hear people talking about math, that impacts our learners. That impacts—like, as a student, that impacts what you think is possible for yourself. So I love this, re-educating ourselves about what math can look like out in the world, in everyday conversations. I don’t know. I really, really appreciated this conversation with Dr. Truglio.
Dan Meyer (39:12):
Same. Yeah. We’d love to hear what you folks think about the work. the book, her ideas. Definitely get in touch with us. Subscribe to Math Teacher Lounge, wherever you get podcasts. And keep in touch with us on Facebook at Math Teacher Lounge Community, and on Twitter at MTL show.
Bethany Lockhart Johnson (39:27):
Also, if you haven’t already, please subscribe to Math Teacher Lounge wherever you get your podcast. And if you like what you’re hearing, please leave us a rating and a review. It’ll help more listeners find the show. And while you’re at it, let a friend know about this episode, because you enjoyed it; they might enjoy it. On our next episode, we’re gonna be chatting with Dr. Heidi Sabnani and taking a closer look at best practices for coaching teachers to reduce their own math anxiety.
Dr. Heidi Sabnani (39:56):
One of the teachers that I worked with had done her student teaching with a teacher who had math anxiety and who never taught math. And so she entered her teaching career never having taught math before or seeing it taught.
Dan Meyer (40:10):
Thanks again for listening, folks.
Bethany Lockhart Johnson (40:12):
Bye.
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Meet the guest
Rosemarie T. Truglio, Ph.D. is the Senior Vice President of Curriculum and Content at Sesame Workshop. Dr. Truglio is responsible for the development of the interdisciplinary curriculum on which Sesame Street is based and oversees content development across platforms (e.g., television, publishing, toys, home video, and theme park activities). She also oversees the curriculum development for all new show production, including Bea’s Block, Mecha Builders, Esme & Roy, Helpsters, and Ghostwriter. Dr. Truglio has written numerous articles in child and developmental psychology journals and presented her work at national and international conferences. Her current book is Ready for School! A Parent’s Guide to Playful Learning for Children Ages 2 to 5, published by Running Press (2019).
About Math Teacher Lounge
Math Teacher Lounge is a biweekly podcast created specifically for K–12 math educators. In each episode co-hosts Bethany Lockhart Johnson (@lockhartedu) and Dan Meyer (@ddmeyer) chat with guests, taking a deep dive into the math and educational topics you care about.
Join the Math Teacher Lounge Facebook group to continue the conversation, view exclusive content, interact with fellow educators, participate in giveaways, and more!
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S3-05: Thinking is power
Join us as we sit down with Melanie Trecek-King, college professor and creator of Thinking is Power, to explore how much of an asset science can truly be in developing the skills students need to navigate the real world. You’ll learn about “fooling” students and the importance of developing critical thinking, information literacy, and science literacy in the classroom. We’ll also share real strategies and lesson examples that help build these essential skills and engage students in learning.
And don’t forget to grab your Science Connections study guide to track your learning and find additional resources!
We hope you enjoy this episode and explore more from Science Connections by visiting our main page!
Melanie Trecek-King (00:00):
We say knowledge is power, but it’s not enough to know things. And there’s too much to know. So being able to think and not fall for someone’s bunk is my goal for my students.
Eric Cross (00:12):
Welcome to Science Connections. I’m your host, Eric Cross. On this third season, we’ve been talking about science’s underdog status. And just this past March at the NSTA conference in Atlanta, I had the chance to speak with science educators from around the country about this very topic.
Hermia Simanu (00:28):
Right now, there’s only two teachers in our high school teaching science.
Shane Dongilli (00:32):
I have 45 minutes once a week with each class. The focus is reading and math.
Alexis Tharpe (00:38):
Oftentimes science gets put by the wayside. And you know, I love math and I love my language arts, but I also think science needs to place be placed on that high pedestal as well.
Askia Little (00:46):
In fifth grade, oh, they teach science, because that’s the only grade that it’s tested.
Eric Cross (00:50):
That was Hermia Simanu from American Samoa. Her team flew for three days to make it to the conference. You also heard from Shane Dongilli from North Carolina, Alexis Tharpe from Virginia, and Askia Little from Texas. All of these teachers were excited to be at the conference and had a lot to say about the state of science education in their local schools. Throughout this season, we’ve been trying to make the case for science, showing how science can be utilized more effectively in the classroom. We’ve explored the evidence showing that science supports literacy instruction. We’ve talked about science and the responsible use of technology like AI. My hope is that all of you listeners out there can use some of this evidence to feel empowered to make the case for science in your own communities. And on this episode, we’re going to examine how science can help develop what might be the most important skill that we try to develop in our students: Good thinking. On this episode, I’m joined by a biologist who actually advocated for eliminating the Intro to Bio course at her college. Instead, Professor Trecek-King created a new course focused on critical thinking, information literacy, and science literacy skills. In this conversation, we discuss why the science classroom is such a good environment for helping students become better thinkers. Now, I don’t think that you can make a much stronger argument for science than using it to develop the skills that Melanie describes in this conversation. So, without further ado, I’m thrilled to bring you this conversation with Melanie Trecek-King, Associate Professor of Biology at Massasoit Community College, and creator of Thinking Is Power. Here’s Melanie.
Eric Cross (02:29):
Well, Melanie, thank you for joining us on the show. It’s so good to have you.
Melanie Trecek-King (02:34):
I am so happy to be here.
Eric Cross (02:35):
Now, I went to your session at NSTA in Chicago … I think it was two years ago. A couple years ago. And I was listening to your session, and as I was listening to you, I started Reverse Engineering in my mind what you were doing with your college students. I started reverse engineering the K–8. I was like, “This is amazing.” Where has what you’ve been doing been hiding? We need this not just in the college, higher ed. We need this all the way up and down. Because I hadn’t seen it before. So I think a good place for us to start is gonna be like the story of how and why you as a biologist wound up making the case to actually eliminate the Intro to Biology course at your college. So can you start off and tell us a little bit about that story?
Melanie Trecek-King (03:20):
Sure. So I started teaching at a community college in Massachusetts. And I absolutely love teaching at a community college. And I was teaching the courses that people who don’t wanna be scientists when they grow up have to take to fulfill their science requirement. And that course was Intro Bio. And I tried every way I could figure out to make that class be useful,] relevant to students. I mean, the thing is, our world is based on science and you have to understand science to be a good consumer of information, to make good decisions. And I’m a biologist, so it pains me to say this, but you know, somewhere in the middle of teaching students about the stages of mitosis and protein synthesis, I thought, “Is this really — like, if I have one semester that’s gonna be the last chance that someone’s gonna get a science education, is this really what they need?” And I just decided, “No.” So, to my college’s credit, they were very supportive. I went to them and said, “You know, I think we should assess the non-majors courses. Like, why do we teach non-majors science?” And we all agreed, well, it was for science literacy. OK, great. Do our existing non-majors courses do that? And so we evaluated each of the courses. I made a case that Intro Bio was not doing it. And so we actually replaced it with a course that I call Science for Life. And the whole course is designed to teach science literacy, critical thinking, and information literacy skills.
Eric Cross (04:48):
And so you did this while you were looking at mitosis. And you’re looking at students who may or may not be science majors. And then kind of asking that question. I know every educator asks this, and whether or not it’s welcomed or supported is a different question: “Is what I’m teaching actually gonna be relevant and useful later on down the road for this group of students?” And you actually got to run with it and then create this course, this new course. So, what were the skills that you were hoping to achieve with the new course you developed, and and why were those skills so important?
Melanie Trecek-King (05:21):
Well, if I just go back for a second to what you said, ’cause it, really hit me: I remember the actual moment — it had been building up to that point, but the actual moment that it hit me — I was teaching students the stages of mitosis. And I was applying it to cancer, because the thought is that if we use issues that are relevant to students to teach concepts, that it will be more meaningful to them. They’ll learn it better; they’ll be able to apply it. And they just looked absolutely deflated. They didn’t wanna be there. And I had this moment where I thought, “You know, if, if these students ever have cancer somewhere in their lives, is what I taught them going to be something that they remember? Is it going to be useful to them?” And quite frankly, like, no. <Laugh> They’re not gonna remember proto-oncogenes. And quite frankly, is that really what they need to know at that moment? What they need to know is, “What does this mean? Who is a reliable source of information here? If these treatments are recommended, what is the evidence for them? What are the cost-benefit analyses? Where do I go to find reliable information?” And in that space, cancer in particular, we have this whole field of — I wanna say charlatans, ’cause they may not actually be lying, but they’re pedaling false cures, false hopes. And people need that kind of hope, and so in their time of need, they’re more likely to fall for that kind of thing. Which leads me to the skills that I teach students. I call them this tree of skills. And the order is important. I start — and there’s a lot of overlap to be fair — but critical thinking, and then information literacy, and science literacy. The idea is that students carry in their pockets access to basically all of human’s knowledge at this moment in time. And if they needed to access it, they could. The question is, do they know what they’re looking for? Are they aware of their own biases that are leading them to certain sources, or certain false hopes? Are there certain things that are making them more vulnerable to the people that might prey on them? Are they able to use that information to make good decisions? There’s a great Carl Sagan quote, and it’s something like, “If we teach people only the findings of science, no matter how useful or even inspiring they may be, without communicating the method, then how is anyone to be able to tell the difference between science and pseudoscience?” So yes, the process of science is a process of critical thinking. However, we do tend to present science most of the time. Like, here’s what science has learned. And to be fair, those things that we’ve learned from science are really useful and inspiring. But if we don’t teach the process, so you’ve got somebody now who let’s say has been diagnosed with cancer and is on their phone and they’re scrolling through social media and everything looks the same. And of course the algorithms learn who you are. Next thing you know, there’s all of these like pseudo-treatments popping up. It all looks the same. Somebody who says that acupuncture can be used to cure cancer can feel the same, from someone who doesn’t understand the process of science, as a medical fact. And so the process is the process of critical thinking. My class everything is open note. The quizzes are open note. The exams — and I say open note, they’re also open online, because I know for the rest of their life they’re gonna have resources available to them; I want them to be good consumers with that information, which to me requires metacognition and critical thinking and information literacy and all those skills that I’m trying to teach them.
Eric Cross (08:58):
You’re basically taking what … we’ve taught science for so long. And more recently, it’s changed to more focusing on skills. At least in K through 12. But a lot of it was just memorization of a ton of different things that now we can pull up our phone, go on the internet. You can pull up a lot of those facts. But those facts don’t necessarily translate to actual real-world skills. When I listen to… I kind of make this analogy sometimes: students say … it’s funny, I have 12-year-olds that say this. They go, “How come they don’t teach us how to do our taxes?” And you know they’re regurgitating what they hear from adults, right? “Teach us real-world skills!” And I was like, really, if we taught you right now how to do your taxes, how many of you would really be like, “Oh, this is an awesome lesson! We’re really engaged!” But their point is that “I wanna learn something that I could actually use later on, that’s that I’m gonna carry on.” And in your course, you’re talking about these skills that actually can apply. Like you said, if I had cancer and I’m looking at different types of medical procedures, do I have the skills to really be able to evaluate and make informed decisions on that? And that’s, that’s not something that I’ve seen explicitly taught really anywhere. And I hadn’t heard anybody talk about it, really, until I heard your session, where you’ve kind of unpacked this, and over the last couple of years, have created some programs or resources for educators, where they can take this into their classroom. So what were some of those skills, again? What were were some of the skills that you thought, “I wanna make sure that my students can walk out and they know how to do this and apply it to maybe several different fields”?
Melanie Trecek-King (10:35):
Oh, that’s a really good question. Because the whole thing was a process for me. Like, when I finally let go of Intro Bio, I was so glad to see that class go, by the way. ‘Cause I just felt like I was beating a dead horse. So when I let go of it, I thought, “What do they need instead?” And for me, what I realized was I was trying to make the class I would’ve wanted to take. I realized the things that I personally didn’t know, that my own education maybe let me down a bit. But things that I thought were important. So then I took all of those, synthesized them, tried to figure out the best order. The class is currently in its third iteration. And I hope every iteration is an improvement. But I’m thinking about the students that I taught before the pandemic. It was Intro Bio. Up to just maybe the couple years before the pandemic, and during the pandemic, we had a new virus and we had a new vaccine and we had new treatments. There was hydroxychloroquine and there was ivermectin and then there’s masks. Are masks effective? Well, you know, in what circumstances? What kind of mask? There are all of these questions. And that whole thing was we saw science playing out in real time.
Eric Cross (11:50):
Absolutely.
Melanie Trecek-King (11:51):
And so were my students able to follow that? And then what happened in that process is that science became politicized. And in a time where things are uncertain and we need answers, ’cause it’s scary, people want certainty and science doesn’t tend to provide that. Especially when it’s just starting out. And then when it becomes politicized, people decide that they’re going to — it’s not necessarily a conscious decision — but they retreat into what people in their camps are saying or their groups are saying. Which actually leads me to one of the more important parts of information literacy skills in there, which is most of our knowledge is shared. We tend to have overinflated senses of what we individually know. And studies actually show that with Google, if you have access to Google, you think you’re smarter than if you don’t have access to Google. But we all have access to knowledge in our communities, and that’s one of the reasons humans are so successful, is that we can each specialize in different things and share our expertise and become greater than the sum of our parts. The problem with that, of course, is that we forget what we don’t know, and we assume that we know what the community knows. And so recognizing the limits of your own knowledge and how different communities produce knowledge, like the different epistemic processes that communities use to come to knowledge. When it comes down to it, an important part of knowing is knowing who to trust, right? Knowing where the source of knowledge lives. And in order to do that, you have to understand the processes that they’re using to come to that knowledge and the limits of your own knowledge. And then how to find who has that knowledge so that you can use that to make better decisions.
Eric Cross (13:38):
So, when I hear what you’re doing with your college students, and I think about what I’m doing in the classroom, in the middle school, we are really focusing on literacy as skills. Reading, writing, speaking, listening. And then when I think of the next step of the journey, your information literacy and the literacy you’re teaching is really the application of those things in the real world. And the examples that you gave are very critical examples. Evaluating claims about Covid. Making informed decisions about a medical procedure that you might need. And we all get that applied to us. We’re scrolling through social media and somehow social media is listening. It’s figuring out exactly what I’m doing, because all of a sudden the ads are telling me … how did you know I was alking about KitchenAid mixers now? I just said KitchenAid mixers and it’s gonna show up in my feed! But <laugh> I take that in the same way from the same place that I take in maybe an oncologist. So it’s it’s coming through the same channels. So now I kind of wanna pivot. So we’ve talked about what you’re doing, why you’re doing it, the connection between “am I really teaching the skills that my students need in the science class? Is it really critical thinking explicitly or is it just kind of implied?” Now I wanna ask you how you do it. What’s the annotated, abbreviated kind of syllabus of your course?
Melanie Trecek-King (15:03):
So the course is called Science for Life. And the premise behind it is the kinds of skills and understanding of the process of science that they would need to make good decisions to be empowered in a world based on science. And so the very first lecture, I say, “OK, I’m gonna tell you a story and I just want you to listen to the story. And at the end I’m gonna ask you why I told the story.” And the story that I tell them is some of the history of the witchcraft trials in Europe. And I start with the Malleus Maleficarum, or the Hammer of Witches, from the Pope, and about how people would accuse witches of causing birth defects or storms or crops dying. And, the best evidence that they had to absolutely know somebody was a witch was if somebody accused them, and then if they were accused, if they confessed. OK? But the problem is, to get them to confess, they would torture them. Roasting over coals, or splitting until somebody broke. And so I tell my students, “OK, this was absolute proof that someone was guilty of witchcraft. I don’t know about you; I would confess to anything, right? Make it stop!” So this is where I get to ask students, “Why would I ask you this? Why would I tell you this story? And traumatize you on the very first day of lecture?” And they see the reasoning, right? They thought they had evidence. The question was, is that good evidence? And so, you know, I’m getting students to have a basic understanding of epistemology, right? Without calling it that, or without going into all of the philosophical background of epistemology. Apply this to your own reasoning. What are you wrong about? Well, you probably wouldn’t know. OK, how would you know if you were wrong? Like what kinds of things do you feel that you’re so right about? How good is your evidence for that? So what I want them to do is internalize the thinking about thinking, and analyzing how they come to conclusions, and proportioning how strongly they believe. Their confidence in how right they are. So I think starting with that kind of misinformation, and getting students to internalize that process is important. But I think the example is really useful, because most of my students don’t believe in witchcraft. Right? So it’s not an issue that would immediately threaten them in some way. So when, when a belief is tied to identity or how we see ourselves or is really important to us, then it’s very difficult to be objective about that belief. And so by starting with witchcraft, it’s not triggering. I get them to think about thinking and practice that muscle so that when we get to those more important issues, they have the skills they need to evaluate them.
Eric Cross (17:55):
So would it be fair to say that your Science for Life class is really applied scientific thinking for the real world?
Melanie Trecek-King (18:01):
Absolutely. That’s the idea. I mean, science is too good to keep to ourselves, right? And it’s everywhere. So how can you understand the world through a scientific lens?
Eric Cross (18:10):
What are the nuts and bolts of how you teach your students these strategies? What do you do? What are some strategies and techniques that we can maybe share with listeners? And then where I want to go after that is I wanna ask you, how early do you think this can be started? So lemme start off first with, what do you do?
Melanie Trecek-King (18:28):
So I use three different strategies. One is, I provide students with a toolkit. And the toolkit is one that I created and it is like my one toolkit to rule them all. It is trying to apply critical thinking and science reasoning all together in one place. So that if students are met with a claim, they’ve got the toolkit with an acronym. They can now start and have somewhere to go. In that if I gave you a claim and said, “Just critically think through this claim,” I mean, that’s a mighty task. But if you have a structured toolkit, then it’s hopefully a systemic way that’s helpful. The toolkit is summarized by FLOATER. I have published it on Skeptical Inquirer. It’s free. So it’s Falsifiability, Logical, Objectivity, Alternative Explanations, Tentative Conclusions, Evidence, and Reproducibility. So I provide students with a toolkit. The next thing I do is I use a lot of misinformation in class. Back to what Carl Sagan says: What I heard was we should use pseudoscience to teach students the difference between a pseudo-scientific process and a scientific process. So, I use science denial, conspiracy theories, and give my students a lot of opportunities to practice evaluating claims with the toolkit. And the other thing I do is, I use inoculation activities. So inoculation theory is based on William McGuire’s original research in the ’60s, which is basically like a vaccine analogy. Where you can inject a small amount of a virus or bacterium into the body, so that it creates an immune response, so that it can learn the real thing. And so in the real world, it can fight it off. Inoculation theory does the same thing, but with misinformation. So, what we can do is, in controlled environments, expose students to little bits of misinformation so that they can recognize it in the real world. There’s different kinds of inoculation, but I’m a big fan of what’s called active and technique-based inoculation. So technique-based means that students are learning not the facts of misinformation, not factually why this thing is wrong, but about the technique used to deceive. So maybe the use of fake experts. Or maybe the use of anecdotes. Or the use of logical fallacies. The other part of that is active, which is where students create the misinformation. So for example, my students, just now, we finished covering pseudoscience. And I teach students the characteristics of pseudoscience. And basically we have fun with it. Where they pretend to be grifters and they sell a pseudoscience product. And so they have to make an ad like they’d see on social media, using the different techniques. And the point there is that it’s supposed to be funny, right? And lighthearted. But in a real way, by using the techniques used to sell something like pseudoscience, it’s opening their eyes. You can’t unsee how every alternative product has, “it’s an all-natural and used for centuries and millions use it and look at this person who says, ‘Wow, it worked for me!’ And it’s certified by some society that doesn’t exist, but this doctor behind it says that it’s really great!” I mean, it’s all the same stuff. So they create the misinformation using their own techniques.
Eric Cross (22:02):
That’s one of my favorite things that you’ve talked about, and I want to dive in that a little bit more. But when you’re teaching the toolkit, FLOATER, what does that look like in the classroom, when you’re actually breaking all of those things down? What does it look like as you’re walking your students through this, and you’re kind of coaching them on all of those different things? ‘Cause I feel like some things might be like, “Oh yeah, I got that.” And then some of them might be, “Oh, what is that?”
Melanie Trecek-King (22:24):
Yeah, it takes me probably a good solid lecture to get through the basis of the toolkit. But then over the rest of the semester, I’ll spend more time going into different parts, different rules, a bit more in-depth. So, for example, logical fallacies and objectivity. So the rule of objectivity basically states that you need to be honest with yourself. I’m gonna quote Feynman here, so: “The first principle is that you must not fool yourself — and you are the easiest person to fool.” We don’t tend to think that we can be fooled. But of course we can. So actually, if you wanna talk about it, I start class by fooling my students.
Eric Cross (23:03):
Wait, what do you do? What do you do for that?
Melanie Trecek-King (23:05):
Oh, so this is really fun. Day 1 of class, after the syllabus, I tell my … so you’re in my class now, Eric. “So I have a friend, and she’s a psychic. She’s an astrologer and she’s pretty good at what she does. I mean, she’s got books and she’s been on TV and stuff. She knows I teach this course about skepticism. And so she’s agreed to test how effective she is by providing personality assessments to students in class. So if you wanna participate, what I need from you is your birthday, your full name, answer a few questions. Like, if your house was on fire and you could take one thing, what would it be? Or if you could get paid for anything to do anything for a living, what would it be? Um, there’s a third one. Oh! If you could have any superpower, what would it be?” So the next class, it’s usually over a weekend. The next class I say, “OK, I’ve got your personality assessments back, but remember, we wanna test how effective she is. So in order to do that, I need you to read your profile as quietly as possible. And then I’m gonna have you rate her accuracy on a scale of 1 to 5. OK? So close your eyes; rate her.” Over the years doing this, it’s about a 4.3 to 4.5 out of 5. They think she’s pretty accurate. OK? “So now, if you feel comfortable, get with a person next to you. And I want you to talk about what parts of the personality assessment really spoke to you and, and why, and why you thought she was accurate or not.” And it takes them 5, 10 minutes before they realize they all got the same one. So, this is not my original experiment. It was first done by Bertram Forer in … I think it was the ’50s. And it’s done in psychology classrooms. James Randi made it famous. But the personality assessment itself is full of what are called Barnum statements. So, named after P.T. Barnum. These are statements that are very generic. So, “You have a need to be liked and admired by people. You are often quiet and reserved, but there are times where you can be the life of the party.”
Eric Cross (25:13):
How do you know this about me, by the way? This is a — I feel like you know me right now.
Melanie Trecek-King (25:17):
“There are times where you’ve wondered whether you’ve done the right thing.”
Eric Cross (25:19):
This is getting weird.
Melanie Trecek-King (25:21):
I’m just on fire, right? So these are Barnum statements. They’re the basis of personality assessment.
Eric Cross (25:29):
Mel, can I pause you right there? You said Barnum. Is that the same Barnum, like Barnum & Bailey Circus?
Melanie Trecek-King (25:34):
Yeah. P.T. Barnum, who didn’t actually say “There’s a sucker born every minute,” but we attribute him with that kind of ethos. These statements though, if you read a horoscope or even like personality indicators, like the MBTI, it is basically pseudo-scientific. And it ends up with lots of these Barnum statements. They produce what’s called the Barnum Effect, which is, “Wow, that’s so me! How did you know me?” I could even do more. Like, you have a box of photos in your house that need to be sorted. Or unused prescriptions. And these can apply to nearly everyone, but they produce this effect where we go, “Wow, that is so me!” Right? So by fooling them this way, I get to … well, so the next thing is, “Yes, I lied to you. And I’d like to tell you I won’t do that again. But I’m not going to, ’cause I might. So be on your guard.” But I did it for free. And why did I do it? “I did it because I could tell you ‘I could fool you,’ but you wouldn’t necessarily believe me. So I fooled you, so that you would learn what it feels like to be fooled.” It’s not fun. But we’re gonna make a joke outta this. And students are almost never upset about this ’cause it’s a fun process and they’re all fooled. And again, the point is, I didn’t disprove psychic powers. I didn’t just disprove psychics with this exercise. But I did show you how easy it was to fake. So if somebody is gonna tell you that they can know these things about you through some way, hopefully the evidence they provide should be stronger than something that’s easily faked. Right? Extraordinary claims require extraordinary evidence. If you claim to be able to read my personality based on my birthdate, then I need more than something that you can be taught to do in 15 minutes. So, I fool them to convince them that they could be fooled.
Eric Cross (27:27):
You’re giving them a practice scenario for thinking. And I was thinking about basketball. I grew up playing basketball. And my coach would have our own team be the defenders of the next team we were gonna play, so that we can be prepared for the defense. We were gonna see. Now, when I’m thinking about education, and what you just said reminded me of this, it’s like we’re often just teaching offense. We’re always teaching the plays. We’re always teaching what to do. But we rarely teach defense. What happens when someone comes towards you and, and they challenge you or they come at you with claims? How do we evaluate this? And I think in pockets we do it. We do claim-evidence-reasoning. We present claims and evidence and reasoning. But we don’t always have practice defending them. And I think there’s great resources. There’s Argumentation Toolkit and there’s all these awesome resources that do this. But does that fit? You’re kind of having them practice defense?
Melanie Trecek-King (28:26):
Yeah. You know, that’s brilliant. I never considered that analogy. But, yeah, in the real world, you don’t just get to always try to score all the time. Someone’s gonna challenge you and give you a claim that maybe you haven’t heard before. So how do you think through it?
Eric Cross (28:41):
Yeah. And you become better. So now I’m thinking about how early could we start doing this? For one, I love the idea of lying to your students, because I do that. And it’s just such a fun scenario. How early could we start implementing these strategies or these ideas or these toolkits? In your mind, what do you imagine? How early could we start this with young people?
Melanie Trecek-King (29:07):
Yeah. I’m so glad you asked that question, ’cause honestly, by the time they get to me, it’s almost too late. And I don’t wanna say it’s too late, ’cause it’s never too late. But, oh, we need to start so much earlier! That example that I gave about the selling pseudoscience argument? I have a wonderful colleague, Bertha Vasquez, who’s a middle school teacher in Miami and the director of TIES at CFI. She did this with her middle school students. And quite frankly, their examples were just as good, or in some cases better, than my college students. And they had so much fun with it, too. And she just said that, you know, <laugh>, they actually are more savvy with the kinds of things that they see online than we — I don’t wanna say give them credit for. But almost that we want to believe. My students give me examples of things that are from corners of the internet that I didn’t know existed. And quite frankly, that’s probably a good thing for my own mental health. But students are on there too, like middle school students, and we need to prepare them for the kinds of things that they see in the wild.
Eric Cross (30:13):
So in middle school, definitely. Now, you’ve also done some work in high school as well, right? In Oklahoma? Did you do some. …?
Melanie Trecek-King (30:17):
Yeah.
Eric Cross (30:18):
…some work with high schoolers? What was that like? Did you see any impact there?
Melanie Trecek-King (30:21):
So I didn’t actually do it in Oklahoma. I have taught the course … actually, you were talking about younger kids. I’ve taught the course to high schoolers in my area that are parts of dual enrollment. And they absolutely ate up the curriculum. And they were wonderful, wonderful students. And it was completely appropriate for … they were juniors, actually. But the course has also been taught in Oklahoma, through a dual enrollment program as well. And it was a small sample size. But we have pre-post testing that showed that it improved their critical thinking, their acceptance of science. But anecdotally the head of the program there said that in his years doing this, he’d never seen a course that helped them improve in their other courses so well. So, I felt very rewarded by hearing this. But apparently their critical thinking skills and information literacy skills helped them succeed in their other courses that they were taking. And I love that the students were transferring those skills to other classes. That’s the whole point.
Eric Cross (31:23):
And that’s a big … I think that what you just said is really the core, especially of what we’ve been talking about this season: What you’re talking about and what you’re teaching can transfer and supports literacy. And this is an example of science doing that across all other content areas. So I think that that’s huge, that that was said. What do people say about this course? I know I went on your website, and I looked at some of the comments that some folks were saying, and I know it’s just a snippet, but what do you hear from the education world about this? Because I don’t see it in many places. I see it kind of embedded, sprinkled into different content areas. But you’re actually teaching it explicitly. Do you tend to find positive feedback, overwhelmingly? Or do you get pushback on on some of this? What’s it been like for you?
Melanie Trecek-King (32:16):
I think the biggest pushback — and it’s good pushback, and I would agree entirely — is with inoculation activities, you do need to be careful to, when you debrief students, you wanna tell them why you did what you did and to use their powers for good and not for fooling other people. And I think importantly, for not putting misinformation out into the wild without having context around it. So if you do these kinds of inoculation activities, like if you have your students create pseudoscience ads, don’t just let them put them on social media. Obviously, you can’t control everything that they’re doing. But explain to them why you wouldn’t wanna do that. As far as everything else, I’ve heard really great feedback. You’re referencing my website. So, when I put together the course, I was trying to find resources for students to read. Textbooks are ridiculously expensive and I couldn’t find anything that I really wanted students to buy. So I just started writing, and I put it on my site. I have a site that’s basically the core of the curriculum. More in progress. And then I’ve got some of the topics that we explore and those are all assigned readings. My students are captive, in that I know they want a grade, and for four months they have to sit with me for the entire semester, in that I’ve specifically ordered the content in a way that would be most conducive to them learning these things. On the internet, though, and on social media, ’cause I post on there as well, people come in from all kinds of entry points, and so the goal would be to have them start at the beginning and go to the end. But people … I’m pleasantly surprised that there is an audience for critical thinking and science literacy content out there. And so that really warms my heart. But I am doing more and more for educators. And so I have a section for educators. I put content on there. I put assignments, the assignments that we’ve talked about and more, are on there. And the educators that I’ve had use it have just been really wonderful. Like, I hear great things. If I might, the biggest issue that I’m having is actually reaching educators. I’ve gone to — I met you at NSCA, actually, that was only last summer.
Eric Cross (34:30):
Oh, wow. Wow.
Melanie Trecek-King (34:32):
Right?
Eric Cross (34:32):
Yeah, you’re right. It wasn’t even a year.
Melanie Trecek-King (34:35):
Yeah, I think it was like July last year. So, um, you’ve been to the conferences. And I just went to the last one as well. But I have yet to figure out a way to really get in front of enough educators to share the content. So if anybody’s listening and is interested in learning more, please let me know! <Laugh>
Eric Cross (34:52):
Yes. And we talked about your website, but I didn’t say what the website was. So it’s ThinkingIsPower.com.
Melanie Trecek-King (34:57):
Yes.
Eric Cross (34:58):
And on there, there’s tons of resources. There is the toolkit. And it’s all free.
Melanie Trecek-King (35:06):
Yes.
Eric Cross (35:07):
And there’s a dope t-shirt on there that I just bought today, that Melanie’s actually wearing right now. It says, “Be curious, be skeptical, and be humble.” And I love that. Because I think one of the things that we can’t forget about teaching people how to think and critically evaluating information, sometimes those conversations can become very dehumanizing. And what I mean by that is it sometimes can become, like, intellectual sport, where we forget that there’s a human being on the other other side. And we lose that empathy and compassion. We can kind of see that. It just becomes this intellectual jousting and arguing. And one of the things I know about you, and when you talk about this or you talk about the work that you do, and even the shirt that you’re wearing, there’s this, “be humble.” There’s this human that is never lost in this. And you said it, too: When you’re teaching your students and you’re equipping them with all of these intellectual skills and all of these tools, to use it for good. So to maintain your humanity, to maintain your character, and then to use it to edify and lift people up, not to go out and do harm. That balance, I think, is so, so important. So it’s something that I really appreciate about you and how you teach.
Melanie Trecek-King (36:19):
I appreciate those kind words. Actually—
Eric Cross (36:21):
Oh, of course!
Melanie Trecek-King (36:22):
—and if I might, I sometimes see people using critical thinking like a weapon. It’s like, “I have learned fallacies and I’m just gonna use the tools of critical thinking to tell you why you’re stupid, or why you’re wrong, and why my position is right!” But real critical thinking involves applying those same standards to your own thought processes. And even something like argumentation: the goal of our argumentation is not to BE right; it’s to GET it right. And so we’re on the same team. If we’re arguing about something, if the idea is in scientific argumentation we’re trying to find the truth, which one of us is making a better argument based on the evidence? Can your perspective help me see my own blind spots and vice versa? And the more different perspectives that we have, the more able we are to find whatever reality is. But we are in this together. And so, yeah, I think … I’m glad to hear that that’s coming through. But if you don’t have the kind of humility that says, “You know, I could be wrong,” then you’re never gonna change your mind anyway. So having the humility to say, I’m wrong. <Laugh>
Eric Cross (37:33):
Yeah. You end up just seeing people just defend turf, as opposed to support “look for truth.” And I know for me, my own education journey, I end up with more questions than answers anyways. So I go in trying to find an answer for something and I end up with 10 more questions. And I go, “OK, this is kind of how it is.” You go down this rabbit hole and you just end up with all these different questions. And it forces the humility, because you’re like, “I don’t know! I think this is what it could be, but it could also be these other answers or explanations. So this is just where I’m at, based on what we know right now, at this present time, which might shift.”
Melanie Trecek-King (38:07):
And that sounds reasonable. Yes. Which might shift. Yes.
Eric Cross (38:11):
And especially for us as life-science biology teachers, our content is something that definitely shifts. I know some of the things I teach now are not things that I learned when I was even in middle school. Just because things evolve. They change. We learn, we get new data. That’s just the way it is.
Melanie Trecek-King (38:24):
<Sighs> And Pluto is no longer a planet.
Eric Cross (38:26):
I know. Rest in — well, no, Pluto’s still there. Yeah. It’s no longer a planet. But that was one part of my kindergarten memorizations <laugh> is Pluto being in there.
Melanie Trecek-King (38:36):
Gotta change your mind.
Eric Cross (38:38):
I know. Any words of advice for science educators out there who want to focus more on honing these critical thinking skills and strategies with their own students, but they don’t know where to start? Where would you point them? Or what advice would you give them?
Melanie Trecek-King (38:52):
I think start with what you want the students to know. And not necessarily the FACTS that you want students to know, but start with the skills that you want them to know. And then really be honest with your process. When I designed Science for Life, I started with, “these are the skills that I want students to know.” And everything was in service of that. So this sort of backwards design, I think, helped me follow a path that was more likely to be useful, if that makes any sense. But it really required doing it all over again. So don’t be afraid to question the things that you’re currently doing, even if that’s all you’ve been taught or all you know.
Eric Cross (39:41):
What I’m hearing is, don’t be afraid to question your own assumptions about what you’re doing. And don’t be afraid to adapt or change or modify. Kinda, pivot. Be flexible.
Melanie Trecek-King (39:51):
Yes, be flexible and pivot. And this is where I’m in a different position than middle school and high school educators. Because I have complete freedom over what I teach in my class.
Eric Cross (40:01):
Sure.
Melanie Trecek-King (40:01):
At the end of the semester, I always joke with non-majors that there’s nothing they have to know, which actually gives me a lot of flexibility, because I could teach ’em a lot of different things. So if there are things that you have to teach students, obviously that’s one thing. But I personally think that the way that we’ve been teaching science needs a refresher. A rethinking. And so I would say, “If you want your students to learn science literacy, honestly ask, what does that mean to you? And what would that look like to get to that point?” For me, though, it was also keeping in mind that maybe I didn’t already know the best way to do that.
Eric Cross (40:43):
One of the things you mentioned earlier is trying to reach out to educators. And I know that when we work together, it’s a force multiplier. And what you’re doing is developing skills. And there’s these skills that are happening right now in academia that you’re doing. And then how do we transfer that into middle and high school. Or, I’m sorry, middle and elementary school, high school. We need to get more people into this conversation to kind of brainstorm and figure that out. We have a Facebook group, Science Connections: The Community, where we have educators that gather. That can be one place we start the conversation. And again, I know on your website you’ve been super active on social media; you’ve grown your presence on Twitter and all these different places, engaging with folks. Which is awesome. ‘Cause I know I see your posts and I’m saving the things that you’re posting and I’m thinking of ways that I can do it in my classroom. I’m gonna take that product. By the way, is that on your website, the lesson that you do with the product?
Melanie Trecek-King (41:43):
No, actually. So the article, “How to Sell Pseudoscience” is … I know Bertha Vasquez wrote up a version of it.
Eric Cross (41:50):
Maybe we can grab that. ‘Cause we might be able to put that into the show notes for folks, because she’s a middle school educator. If there’s already something that’s been done for teachers like us, we’re like, “Yeah, let me get that and let me remix it and make it my own!” if there’s already a exemplar out there.
Melanie Trecek-King (42:04):
Yeah, she’s done it. And so I will absolutely share that with you.
Eric Cross (42:08):
So, all season long, we’ve been talking about science as the underdog. We kind of framed it, you know, science oftentimes takes a back seat to math and English. It’s kinda the first thing to go. Or the first area where time can get cut. Because of what gets tested gets focused on, oftentimes. And then in addition to that, when you’re a multi-subject teacher, elementary science isn’t just one thing — it’s every field. You know, you’re a biologist, which is different than a geologist. And when you’re teaching every subject, that’s a lot. And you might not have had a science class for years. And the realities that we’re seeing over and over with different researchers and practitioners is that science could actually enhance literacy, and building those skills. And I think you really talked about it with the critical thinking skills. Those can transfer. Or the administrator that said, “This is one of the only courses I’ve seen where it transfers to other areas.” Could you share maybe with our listeners, just any advice for advocating for science in their own world?
Melanie Trecek-King (43:13):
Wow, I’m not sure I’m qualified to answer that question! One of the things that comes to mind though — because I was listening to your last episode and educators … I honestly didn’t realize how little time they had for science. And how often science was then the first to go, to allow room for other subjects. But science overlaps with a lot of other issues. And so I feel like there could be a way to bring in science when teaching these other subjects. So, for example, argumentation and logical fallacies are easy to apply to reading and writing. Information literacy, and being able to find good information online, teaching students how to laterally read, to be able to check a source, or how to use Google effectively, to put in neutral search terms to find sources, or teaching students how to recognize the characteristics of conspiratorial thinking: All of these things can overlap with so many other subjects. So the scientist in me is a little biased towards science being important enough to do this. But try to bring it into the other subjects. It doesn’t have to be completely separate.
Eric Cross (44:43):
So integrating science into other things. And I … big believer. And a hundred percent agree with you. Now I’m gonna ask a question that kinda like takes us backwards. You shared an app with me when we first met that I thought was really cool. And I know it’s a friend or colleague of yours. But as a middle school teacher, I thought it was great, because it was something that my students could download and practice some of the skills that you’re talking about. Would you talk a little bit about the cranky uncle? Is it the Cranky Uncle app?
Melanie Trecek-King (45:17):
Cranky Uncle.
Eric Cross (45:18):
Could you share a little bit about that?
Melanie Trecek-King (45:20):
Yeah. Cranky Uncle is awesome. So, Cranky Uncle is the brainchild of John Cook, who is the founder of Skeptical Science and the author of the 97% Consensus study on climate change. Cranky Uncle … so he’s also a cartoonist. And Cranky Uncle is a cartoon game where … I don’t even have to explain who Cranky Uncle is to my students. Everybody inherently gets the, the character, right? So he’s like the guy at Thanksgiving that you don’t wanna talk to because he denies climate change and he’s just really cranky. But Cranky Uncle uses the techniques of science denial, which are summarized by the acronym FLICC: So it’s Fake experts, Logical fallacies, Impossible expectations, Cherry-picking, and Conspiratorial thinking. So he uses those techniques. Again, this is technique-based inoculation. So they recognize the techniques in the game, and you earn cranky points. And as you make Cranky crankier and crankier because you’re recognizing his techniques, you learn the techniques of science denial, and level up and open up other techniques. This is another one of those examples where climate change has a lot of science behind it, right? And if you wanted to get to the science behind climate change for any particular issue … so let’s say it’s cold today, so I’m gonna say there’s no climate change. OK? If I’m gonna unpack that at a factual level, and with science, we could be here for a while. But if I told you, “That’s like saying, ‘I just ate a sandwich so there’s no global hunger.’” OK? So that’s a parallel argument. Humorous. Love to use this kind of argumentation, ’cause it makes for some … I mean, it’s funny, but you get the point. It’s an anecdote. And anecdotes aren’t good evidence. So just like that, you could teach the technique of using an anecdotal fallacy for climate-change denial. So, I have my students play this game. You could do it when you’re studying argumentation. You could do it for science denial. I use an inoculation extension with that, where I have my students pretend that … um, actually, back up for a second. So I teach a class on critical thinking. And at the end of semesters I would get emails from students on, well, they’re failing the class, but they really shouldn’t, for all of these reasons. And reading these emails, I’m like, “If you think that’s a good argument, you clearly didn’t learn what I was hoping you would learn.” So I now have my students, early in the semester, after they play Cranky, pretend that it is the end of the semester and you’re failing the class and you’re failing because you didn’t do the work. Use at least four of the fallacies from class to argue for why you should pass. So they have to put it on a discussion forum, and they’ll say things like, “Well, if you fail me, then I won’t get into graduate school and then people will die and it will all be your fault.” Or, “My dog died, and so I was really sad.” Or, um, “You’re just a terrible teacher. And you’re short. So I don’t like you.” Or that kind of thing. So, oh, they love to attack my character. It’s really funny. But it’s supposed to be funny. And the point is, the students are using those arguments, they’re using the fallacies, to argue for something. And so by creating that misinformation themselves, they learn how those fallacies work. But taken together, I mean, everything that we just talked about there, Cranky Uncle, and the fallacy assignment, or whatever iteration you want that to be in, that doesn’t have to be in a purely science unit. Right? That could be sociology. It could be argumentation. It could be English.
Eric Cross (49:01):
Absolutely. That could be totally a prompt in an English class. And practiced in there. And then this could be an interdisciplinary thing, going back and forth between English and and science. Just having these discussions and looking at it from different angles. And you’re practicing the skills in two different contexts. So you get into argumentation. And then that app, I know I had fun with it. And the questions on there definitely resonate with people in my own family. I’m like, “I feel like I’m talking to exactly somebody that I’m related to right now.” <Laugh> Melanie, anything else that you wanna share, or discuss or highlight, before we wrap up?
Melanie Trecek-King (49:39):
So we could talk about lateral reading, if you like. ‘Cause I know a lot of educators use the crap test.
Eric Cross (49:45):
Please, please, please talk about that.
Melanie Trecek-King (49:47):
So, when evaluating sources, a lot of educators teach what’s called the CRAP test. And I wish I remembered what it stood for. But basically what you do, a lot of us have been taught when you go to a website, to figure out if it’s reliable, you wanna go to the about page. Read the mission; see who they are; maybe read some of the content; evaluate the language. So is it inflammatory? Are they making logical arguments? Are the links to reputable sources as well? And the problem is that if a site wants to mislead you, they’re not going to tell you that it’s a bunk site, right? They’re just gonna do a good job of misleading you. And so, what you wanna do instead … the CRAP test basically is an evaluation of a site. And that’s what’s called vertical reading. So you’re looking through a site to determine if it’s reliable. Uh, I think his name’s Sam Wineberg at Stanford, proposed something called lateral reading. Where, instead of on the site, what you wanna do is literally open a new tab and into the search engine type the source. You could do the claim, too. And then something like Reliability or FactCheck or whatever it’s that you’re checking, and then see what other reputable sites have to say about it. So, in their study, actually, they did a really interesting study where they compared professional fact checkers to PhD historians to Stanford undergrads. And they evaluated — I wish you could … um, there’s two pediatrician organizations. One’s like the American Association of Pediatrics and the American Academy of Pediatricians, something like that. They’re very similar sounding. So you give them to students. I do this with my students as well, the same study. So I give my students those two websites. And I say, “Which one of these is more reliable?” And they do exactly what most of us do, which is spend time on the site looking around. And most of the time, if not nearly all the time, they come to the wrong conclusion. And so then I tell them what lateral reading is: “OK, instead of looking through the site, open a new tab, search the organization and reliability.” Something like that. And it takes probably 30 seconds before they realize one of them has been dubbed by the Southern Poverty Law Center as a hate group. As opposed to the other one, which is like a hundred year old huge pediatrician organization that produces their own journals and so on. But nearly all my students are fooled. And in the study, none of the fact checkers were fooled. I’m gonna get the number right. It’s something like 50% of the historians and 20% of the Stanford undergraduates got the correct answer. And they spent a lot more time on it. So it’s a great way to teach students how to use the power of the internet to evaluate sources much more quickly and, effectively. And yes, use Wikipedia, right? Wikipedia is not a final answer, but Wikipedia is actually pretty accurate. So if Wikipedia is the first place you stop, then yes, go there, see what Wikipedia says, and then follow some of their sources.
Eric Cross (52:47):
What popped in my head was like, Yelp reviews for websites. That almost sounds like what it was. It’s like when I search for a product, I don’t go and read the product description marketing. ‘Cause that’s all designed to sell me on something. But I’ll go and look in Reliability, if it’s like a car, or just other sites to cross-reference. And that sounds like what you were talking about is like cross-referencing. Seeing what FactChecker [sic] said about this site, versus seeing what a site says about itself.
Melanie Trecek-King (53:14):
Well, that’s a great analogy. Because if I wanted to know if a product was effective, what the manufacturer says about the product, clearly there’s a strong chance of bias. Right? They’re going to be on their best, um, put their best foot forward. Versus, what do independent reviewers say about this product?
Eric Cross (53:35):
Yep. And I am known to research something to death. And I get something called “paralysis by analysis.”
Melanie Trecek-King (53:42):
Ohhhh, yeah.
Eric Cross (53:44):
And it’s so bad that even if I’m trying to buy, like, towels, I need to find the best-bang-for-the-buck towel. I have to defer some of these decisions out, because I’m on the internet for three hours now. I’ll be a pseudo-expert in towels, and thread count, and all of that stuff. But yeah, that maybe that’s just the science person.
Melanie Trecek-King (54:03):
I mean, I feel your pain. I do the same thing. <Laugh> It’s annoying. Like, it’s just towels. What does it really matter? But yeah.
Eric Cross (54:10):
Coffee! It doesn’t matter what it is. I just need to go, “OK, I have to use these powers for good. Otherwise I’m gonna be researching forever.”
Melanie Trecek-King (54:16):
I wanna say one other thing. So, again, this is a college class and I have a lot of freedom. But one of the driving philosophies behind the class is a wonderful quote in a book, Schick and Vaughn, How to Think about Weird Things. And they said, “The quality of your life is determined by the quality of your decisions, and the quality of your decisions is determined by the quality of your thinking.” And I know my students want a grade. But I’m really trying to teach them how to be empowered through better thinking. That’s where the name “Thinking is Power” came from. I mean, we say “Knowledge is Power,” but it’s not enough to know things. And there’s too much to know. So being able to think and be empowered to have your own agency and not fall for someone’s bunk is my goal for my students.
Eric Cross (55:07):
And doing that is gonna help them through the rest of their lives. Not be swindled, not be taken advantage of, be able to make better decisions. There’s so many benefits to building that skill. And I know your students have definitely grown and benefited. I’m sure you’ve heard, long after you’ve taught them, heard back from them and how they’ve applied that course to their lives. Melanie, thank you so much for being here. For a few things. One, for providing and filling this space where there’s such a need. Again, the critical thinking resources, the tools that you used, are so, so important. If we ever lived in a time where they were critical, it was really what we experienced during the pandemic in the last few years. We watched people’s information literacy and science literacy play out in real time. And we literally saw life-and-death decisions being made based off those skills. That highlighted, I think how important this is. And then, taking the time to generate resources for educators like myself, that we can take and adapt and put into our classroom and start teaching our students. ‘Cause like you said, by the time they get to you, they’re, they’re so far downstream or so far in a system that, depending on the teachers that they’ve had and the education system they’ve been in, may or may not have even touched on these things. They might have learned a lot of facts, but they may not have built their muscle to be able to critically analyze and interpret the world around them. And you’ve just — even the last year, it hasn’t even been a year since we talked the first time — I’ve watched your resources continue to grow, and you share them. And so I, on behalf of those of us in K–12, thank you. And thank you for being here.
Melanie Trecek-King (56:49):
Oh, well, thank you so much for this opportunity. Thank you for everything that you do, reaching out to other educators and for giving me a platform to hopefully reach other educators.
Eric Cross (57:00):
Thanks so much for listening to my conversation with Melanie Trecek-King, Associate Professor of Biology at Massasoit Community College and creator of Thinking Is Power. Make sure you don’t miss any new episodes of Science Connections by subscribing to the show, wherever you get podcasts. And while you’re there, we’d really appreciate it if you can leave us a review. It’ll help more listeners to find the show. You can find more information on all of Amplify shows at our podcast hub, Amplify.com/Hub. Thanks again for listening.
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Meet the guest
Melanie Trecek-King is the creator of Thinking is Power, an online resource that provides critical thinking education to the general public. She is currently an associate professor of biology at Massasoit Community College, where she teaches a general-education science course designed to equip students with empowering critical thinking, information literacy, and science literacy skills. An active speaker and consultant, Trecek-King loves to share her “teach skills, not facts” approach with other science educators, and help schools and organizations meet their goals through better thinking. Trecek-King is also the education director for the Mental Immunity Project and CIRCE (Cognitive Immunology Research Collaborative), which aim to advance and apply the science of mental immunity to inoculate minds against misinformation.
About Science Connections
Welcome to Science Connections! Science is changing before our eyes, now more than ever. So…how do we help kids figure that out? We will bring on educators, scientists, and more to discuss the importance of high-quality science instruction. In this episode, hear from our host Eric Cross about his work engaging students as a K-8 science teacher.
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Rethinking reading comprehension
Have you ever listened to a student read aloud fluently about something—say, the life cycle of sea turtles—only to discover afterward that they couldn’t explain a single thing about…the life cycle of sea turtles? It’s a familiar classroom moment, and it reveals how easy it is to misunderstand what comprehension really is.
Comprehension is often framed only as the product of reading: the answers students give when asked to find the main idea, identify a theme, or summarize a passage.
But the Science of Reading tells us that comprehension is more than an outcome. Comprehension is also a dynamic process that unfolds as readers move through a text, powered by the interactions among words on the page and the knowledge and reasoning they bring to it. That’s why we like to think of it as the heartbeat of literacy.
Why comprehension is both product and process
For decades, much of classroom instruction has focused on language comprehension products: the demonstrations of understanding that happen after reading. Those are important, but they don’t tell the whole story.
That’s because products depend on processes. If students do not build a coherent mental model of what they’re reading—while they’re reading—they may succeed at reading, but not at comprehending.
This is the missing link that researchers like Hugh Catts, Ph.D., and Jane Oakhill, Ph.D., have revealed: Comprehension isn’t something readers suddenly have at the end of a passage. It’s also something they do all along the way.
What comprehension processes look like
Comprehension processes are the mental moves students make to construct meaning as they read. All students need explicit instruction and practice in order to learn to do this automatically. Some of the most important processes include:
- Inference-making: Filling in gaps the author leaves unsaid. If a story says “Carlos forgot his umbrella and got wet,” readers must supply the missing piece: It rained.
- Anaphora resolution: Figuring out who pronouns such as he or she refer to. For instance, in a passage where “Charmaine passed the ball to Kendra, and she scored,” not all readers may track that she refers to Kendra.
- Monitoring meaning: Noticing when something doesn’t make sense and rereading to fix it. Think of a student breezing through a science lab procedure but not realizing they’ve misunderstood a key step.
- Recognizing connectives: Using words like because, however, or meanwhile to understand how ideas fit together in a text about history, math, or literature.
- Visualizing: Building a mental picture—whether that’s of how a caterpillar becomes a butterfly, or how a character’s feelings shift across a story.
When these processes don’t happen, comprehension breaks down—even for students who can decode fluently. That’s why teaching comprehension can’t mean just assigning comprehension questions. It has to mean teaching students how to think with text in real time.
The role of knowledge and writing
Processes don’t exist in isolation. They depend on, and are strengthened by, what students already know and what they can express in writing.
- Knowledge: The more background students bring to a text, the easier it is for them to make inferences and connect ideas. A child who already knows a little about baseball will understand a passage about a pitcher’s strategy much more readily than one encountering the game for the first time.
- Writing: Writing about reading reinforces comprehension. When students summarize a biography in their own words, draft a response to a novel, or synthesize ideas from multiple sources, they are practicing the very processes—like making connections and organizing ideas—that skilled readers rely on.
This interplay—reading feeding knowledge, knowledge feeding comprehension, writing reinforcing both—creates a cycle of literacy growth that goes far beyond the end-of-text quiz.
Rethinking classroom practice
Working on individual comprehension skills can help in the short term. But long-term literacy success—for all students—requires explicit instruction and practice in all the comprehension processes needed to build comprehension products.
So what does it mean to teach comprehension as a process, not just a product?
Weaving effective instruction in comprehension strategies into everyday literacy work. A few examples:
- Model your thinking. Pause mid-reading to ask, “Who does she refer to here?” or “That didn’t make sense—let’s go back.”
- Highlight connectives. Teach words like although or consequently explicitly, showing how they signal relationships between ideas.
- Promote monitoring. Encourage students to ask themselves, “Does this make sense?” and to reread when it doesn’t.
- Build knowledge deliberately. Use content-rich texts in science, history, and the arts to give students the context they need for stronger comprehension.
- Pair reading with writing. Even short written responses—“Why do you think the character acted that way?”—help solidify understanding and make comprehension processes visible.
These practices shift comprehension instruction from an after-the-fact check to an in-the-moment skill set students can carry into every subject.
Want to dig deeper?
Expanding our understanding of comprehension as both product and process is one of the most important shifts the Science of Reading has brought to literacy instruction. It reminds us that comprehension isn’t just a mysterious outcome at the end of reading—it’s the ongoing work of making meaning along the way.
To help educators explore this shift, we’ve created the new Science of Reading: Comprehension 101 bundle. These resources break down the research and provide strategies you can use right away. When we teach comprehension as the ongoing process it truly is, we keep the heartbeat of literacy strong for every reader.
Inside, you’ll find the following resources:
- Our anchor ebook: Understanding Comprehension: The Heartbeat of Literacy
- Infographic: The missing link in reading comprehension
- Ebook: Knowledge, Reading, and Writing: The Secret Recipe for Literacy Success
- Podcast: “Science of Reading Essentials: Comprehension” episode and listening guide
- Webinar: Rethinking Reading Comprehension: Reflections on Hugh Catts’ and Jane Oakhill’s Research
Frequently asked questions
Still have questions? We have answers. Check out the following FAQ.
Overview
- Amplify CKLA is based on research showing that closing the background knowledge gap is necessary for supporting the literacy development of all students. To that end, Amplify CKLA teaches literacy through the lens of cross-curricular domains in science, history, literature, and culture. It was developed in response to research that shows the critical impact of background knowledge on reading comprehension and college- and career-readiness.
- The program also reflects the latest early reading research showing the importance of explicit foundational skills instruction. The program develops students’ foundational literacy skills through a systematic scope and sequence with a focus on phonics.
Our research-based language arts curriculum is built on findings showing that higher-level reading comprehension depends on both automatic, fluent decoding and background knowledge. Combining well-established findings from the field of early literacy research with classroom-based feedback, Amplify CKLA ensures that children will learn to listen, speak, read, and write confidently and proficiently. For more information, view the Amplify CKLA Research Guide.
Amplify CKLA is a PreK–5 program. While the PreK and K–2 materials respect the important differences between early childhood education and formal schooling, the Grades 3–5 materials ensure a smooth transition to the academic rigors of middle school.
PreK
The focus in PreK is to maintain a developmentally appropriate early childhood setting; the structures, routines, and activities are engaging and children receive a solid foundation for future language arts instruction.
K–2
The focus in K–2 is developing fluent reading and writing skills, and enhancing language comprehension by building background knowledge and vocabulary. This is accomplished through two strands: the Skills Strand and the Knowledge Strand.
The Skills Strand focuses on decoding, encoding, grammar, handwriting, and the writing process, and it contains decodable chapter books for students to practice just-learned sound-spellings.
The Knowledge Strand builds background knowledge and vocabulary through carefully sequenced read-alouds and complex texts. Teachers read aloud stories that are more complex than the text students can decode on their own, enabling children to engage with complex texts and build background knowledge of a variety of connected topics in history, science, literature, and the arts.
3–5
In Grades 3–5, students are still focused on building reading and writing skills as well as knowledge and vocabulary, but the program no longer has two strands. The various lessons in each unit include read-alouds; whole-group, small-group, and partner reading; close reading; literal, inferential, and evaluative comprehension questions; vocabulary; grammar; writing; morphology and spelling (10–15 words per week); and unit assessments.
Program design
The Skills strand provides intentional and systematic support in building decoding skills. The lessons support learning related to phonemic awareness, sound-letter patterns (or spelling patterns), decoding (both in explicit lessons and with engaging decodable texts), writing mechanics, and writing structure and processes, for 60 minutes daily.
The Knowledge Strand develops young children’s language and background knowledge. By exposing children to rich and complex texts through daily read-alouds, engaging in text-based and analytic discussions of the text and content, and building connections from the text to the work of the classroom through extension activities, the Knowledge Strand provides daily, extensive (60 minutes) broadening and deepening of children’s oral language and comprehension.
Teaching the Skills Strand and Knowledge Strand in parallel helps students avoid cognitive overload and acquire advanced, complex vocabulary in the Knowledge Strand—in essence, reading to learn from day one—while becoming expert decoders in the Skills Strand. The program is designed to bring these two strands together in grades 3–5, as foundational skills and higher-level comprehension and meaning-making gradually intertwine.
The CKLA program takes a comprehensive approach to teaching the code of the English language in the Skills strand. While the English language has only 26 letters, these letters combine to create 150 spelling patterns that represent 44 sounds of language. In most reading programs, children are explicitly taught only a fraction of this information and must glean the rest from ad hoc and incidental exposure to these spelling patterns through text. CKLA focuses on explicitly teaching each of the 44 sounds and the 150 ways that these sounds are represented (via letters and letter combinations). This comprehensive approach assures educators that children have the knowledge they need to address any text and any word.
The Knowledge Strand reflects the fact that knowledge, comprehension, and vocabulary are intimately related. The materials are designed to provide children sustained time on a variety of domains (bodies of knowledge) through shared read-alouds and discussions. This coherent organization of content is critical to building knowledge, inferring new vocabulary, and enabling comprehension. The content-rich, intentionally sequenced nature of the read-alouds within the Knowledge Strand creates the optimal context for incidental and explicit vocabulary-learning opportunities. After the read-aloud, children analyze the text through interactive discussion questions, engage in activities that foster their comprehension of complex sentences and ideas, and extend the ideas of the read-aloud into other activities in the classroom. In this way, the lessons create rich, academically oriented, oral language experiences that promote both receptive and expressive language skills.
Amplify CKLA embeds a variety of diagnostic and classroom assessments into the program materials.
There are curriculum-based assessments of both foundational skills and content knowledge, placement assessments in Grades 1 and 2 for the Skills Strand, and end-of-year Skills Strand assessments in Grades K–3. These assessments are built into the units of instruction/domains within the Teacher Guides. In Grades 4–5, there are beginning-of-year assessments, frequent spelling assessments, and comprehensive unit assessments.
Formative Assessments are integrated into every lesson, allowing teachers to understand exactly how students are doing on meeting lesson goals and standards-based objectives.
Writing in multiple genres is taught through a process that builds from three highly scaffolded steps to seven flexible steps.
In addition to explicit lessons in handwriting, spelling, and grammar, writing is taught throughout K–5. Instruction begins with a three-step writing process: plan, draft, and edit. The process is reinforced as each new writing genre is addressed. Each genre is taught through a gradual reduction in scaffolding over a set of six lessons that includes teacher modeling, group practice, independent practice, and independent application. This systematic approach allows for continued support and predictable learning as children progress in their knowledge of text types and complexity of writing. By Grade 3, students have worked their way up to a five-step writing process: planning, drafting, revising, editing, and publishing. Beginning in Grade 4, the writing process expands to seven components: planning, drafting, sharing, evaluating, revising, and editing (and the optional component of publishing). An important change between the writing process in Grades 3–5 is that the writing process is no longer conceptualized as a series of scaffolded, linear steps that students follow in a set sequence. Rather, students move back and forth between components of the writing process in a flexible manner, similar to the process that mature and experienced writers follow. In addition to specific writing lessons, there are numerous writing opportunities for students throughout the curriculum.
Alignment to the CCSS
Fully implementing the Common Core Standards requires some shifts in prevailing instructional approaches. For early grades language arts, these shifts can be summarized as (1) balancing fiction and nonfiction text, (2) building knowledge, (3) supporting students’ capacity to learn from increasingly complex texts, (4) giving text-based answers, (5) writing from sources, and (6) explicitly supporting the acquisition of academic vocabulary. The following sections document the primary ways that Amplify CKLA meets the demands of these shifts.
- The amount of nonfiction gradually increases, reaching the 50-50 balance of fiction and nonfiction by grade 3.
- Read-alouds in the Knowledge Strand are designed according to the latest research to build knowledge and vocabulary in history, science, the arts, and more.
- The texts in both the Knowledge Strand and the Skills strand increase in complexity as the program progresses within and across grades.
- In the Skills Strand, the language and knowledge demands of the texts increase, but remain decodable based on the aspects of the code that have been taught to date.
- Both strands engage students in appropriate means of providing text-based answers—orally, pictorially, and eventually in writing.
- Together, the Skills and Knowledge Strands enable students to read and digest various sources and then write by drawing on those sources.
- In both strands of the program, Amplify CKLA teaches children the process of using the text as a springboard for understanding.
- The Knowledge Strand offers repeated exposures to academic vocabulary through authentic texts and explicit word instruction.
Materials
PreK
- Teacher Guides, Student Activity Pages, 3–4 Trade Books per domain, Flip Books, Image Cards, Transition and Center Cards, Nursery Rhymes and Songs Posters, and a Big Book (Classic Tales)
Grades K–2
- Knowledge Strand: Teacher Guides, Flip Books, Student Activity Books, Image Cards, and online resources including supplemental lessons
- Skills Strand: Teacher Guides, Activity Books, Student Readers, Big Books, Letter Cards, Spelling Cards, Individual Code Sheets, Code and Chaining Resources (Vowel/Consonant Code Flip Books, Student Chaining Folders), Blending Cards, and online resources including differentiation and remediation guides
Grades 3–5
- Teacher Guides, Student Readers, Activity Books, Poet’s Journal, Writer’s Journal, Core Quests (The Viking Age in Grade 3, Eureka: Student Inventor in Grade 4 and “A Midsummer Night’s Dream” in grade 5) and Writing Quests (The Contraption in Grade 4, The Robot in Grade 5)
S3-03: Instructional strategies for integrating science and literacy
We’re continuing our investigations around science and literacy with Doug Fisher, Ph.D., professor and chair of educational leadership at San Diego State University. We talk about the importance of integrating science and literacy, as well as practical guidance for teachers who want to unite the two disciplines in their own classrooms.
Listen as we discuss how science and literacy can be powerful allies and specific strategy areas to focus on when integrating the two disciplines. And don’t forget to grab your Science Connections study guide to track your learning and find additional resources!
We hope you enjoy this episode and explore more from Science Connections by visiting our main page!
Douglas Fisher (00:00):
It’s not that you have to become a reading specialist to integrate literacy into science. It’s how our brains work.
Eric Cross (00:10):
Welcome to Science Connections. I’m your host, Eric Cross. This season, we’re making the case for our favorite underdog, which of course is science. Each episode we’re showing how science can be better utilized in the classroom, and making the case for why it’s so important to do so. In our last episode, we examined the evidence showing that science and English instruction can support each other. And now on this episode, we want to give you some more strategies for really making that a reality in your own home or classroom or community. So to help me, I’m joined on this episode by Dr. Douglas Fisher, Professor and Chair of Educational Leadership at San Diego State University. Dr. Fisher is actually someone who has conducted literacy training at my own school, so I’m excited to be able to share some of his wisdom with all of you. Oh, and just a heads up, Dr. Fisher dropped some gems about the ways teachers can integrate literacy and science in their classrooms. So you may want to have a notepad. Ready. And now here’s my conversation with Dr. Douglas Fisher.
Eric Cross (01:12):
Well, Doug, thank you for your time and for being willing to come and talk about literacy and science. I know you’re busy, all over the place, and so I was super-excited that we were able to lock you in and talk about this. And, on this episode, we’re gonna talk about the ways that science and literacy can support each other. And one of the reasons why I’m really excited for you is because you said some really key things for me as a science teacher, when you talked about literacy and supporting students. That just resonated so deeply in me. And I was like, “I need more Doug!” Because we’re on that same frequency. And I know it’s a subject that you’ve spent a lot of time writing about. So can you tell us a little bit about how this became an area of interest or a passion for you? Just literacy, and all of the work that you’ve put into it?
Douglas Fisher (01:54):
Yeah. So I’ve wanted to be a teacher for a really long time. And I went to San Diego State as an undergraduate, and I was taking English class and we were assigned topics. You know, like, you’ll do an assignment, you’ll write a paper for this English class. And I got the topic “illiteracy,” and I was a freshman at San Diego State reading all of these things about adults who don’t read very well or not at all. And I ended up writing my very first college essay on illiteracy — at the time, you know, called illiteracy, at the time. And so I got super interested in this. And so as I moved through college and into my teaching career, literacy became a really important thing for me to think about, because it’s the gatekeeper. You know, you can be taken advantage of, if you’re not very literate. People can use vocabulary against you, if you’re not very literate. We know that people who have higher levels of literacy have better health outcomes. They have better lifespans, longer lifespans. I mean, there’s just — literacy impacts so much more than “Are you reading your fourth-grade textbook?” It really has lifelong implications.
Eric Cross (03:01):
That part that you said about being taken advantage of … I just got a flyer in the mail yesterday. It was one of these mailers that looked like it was an authentic debt-reduction type of thing, but it was really just like a marketing email. If you read the fine print at the very bottom, it had all of this jargon about “This is a paid, you know, for-profit company.” But when you look at it, it had official stamps all over it. And I could imagine if someone’s receiving that, that probably fools a lot of people. Is that kinda like what you’re talking about, like being taken advantage of?
Douglas Fisher (03:28):
Yes. I had a student turn 18, got a letter from a “credit card company” that was offering her daily compounding interest. And if you don’t know what that means — at 23 percent! — if you dunno what that means, you are gonna be a victim. Literacy really influences a lot of our life. It’s also how our brain works. We have a language-based system in our brain. We read, write, speak, listen, and view. And the things we learn, we learn through speaking, reading, writing, listening, and viewing. From what we know, we are the only species that has an external storage mechanism. Like, we have the ability to store complex information outside of our body, in the form of notes. We can type them. We can write them. And we can then go back and retrieve that information, that complex orthographic information later. And it means the same thing. We can say we have a storage system and we’ve been doing this for a really long time. Way back to, you know, hieroglyphics and messages on cave walls. And throughout the ages of humans learning, how to store information that they can re-access again later. That’s become a super-complicated system. It’s how computers operate. And we send messages to each other and we text each other and we write things down, and we’re really good at putting ideas, information out there. Now, if it’s just speaking and listening, then we can forget it. We can say, “No, you said this,” or “I said that.” But when it’s written, and it’s print literacy, you know, it’s the orthographics there, you can go back to the same message and over and over again. Now, you might change the interpretation of it, but the message is still there.
Eric Cross (05:16):
Right. And that is such a key element, at least of modern education, is this written element of it. It’s what many schools live and die by. They’re quantitatively and qualitatively analyzed by it. It’s public. They can see it. And so there’s this heavy emphasis. And why do you think science and literacy can be powerful allies together?
Douglas Fisher (05:38):
Awesome. Well, it’s hard to learn science if you’re not literate.
Eric Cross (05:42):
This is true.
Douglas Fisher (05:42):
But that’s a one-way direction. And yes, science teachers and scientists do a lot of reading, writing, speaking, and listening and viewing. They use the five literacy processes all the time. When we interview scientists, they spend a lot of their time reading the work of other scientists and writing their findings, writing grant proposals, presenting at conferences, you know. So a huge part of the work of a scientist is not just at a bench conducting experiments. But even if you’re conducting experiments, you’re using your literacy processes to think about what you’re seeing in your experiment. So that’s a one-way direction. And I do think literacy has an influence on science. But since science goes the other way, it influences literacy. As you learn more and you understand more about the world, your background knowledge grows, your vocabulary grows, you become more literate in those different areas. And how you think. So if I’m learning about life science; I’m learning how the world works in a more, biologic physical world. And that knowledge helps me think about when I’m reading a novel, and there’s an appeal to some science knowledge or a concept that gets played with, you know, perhaps time-space continuums … well, if I don’t have the science knowledge of how I think the world works, it’s hard for me to understand what this author is doing. So it does go both ways. They feed each other. And the more literate we become, the more complex science information we can understand. ‘Cause our background knowledge and our vocabulary influence how much we understand about what we read. And as we access more complex science information, it starts to change the way we think about other things in our world.
Eric Cross (07:23):
There was a couple of things that you said in that, but one of the first things that kind of perked my ears is when you said grant proposals. Because I have friends that are scientists — and this is one of the things that when I was in school, they don’t talk about — but how much of their research is reliant upon getting funding —
Douglas Fisher (07:37):
Mm-hmm. <affirmative>,
Eric Cross (07:38):
— which you don’t think about if you’re becoming a chemist or a physicist or a biologist or working in the field, is that that funding, coming from the NSF or anywhere else. And sometimes students ask in class like, “Why am I writing so much? Like, I want to go into science!” Or “I wanna do this!” And this is a real-life example of how the writing could actually apply, in addition to all of the things of collecting data and conclusions and results. But that grant proposal thing just really perked my ears, yeah.
Douglas Fisher (08:01):
And if you can’t write a grant proposal, your ideas and experiments are not gonna get funded. And if you can’t write a strong proposal, that compellingly convinces your readers to fund you, you’re not gonna get funded. But then once you get the grant, you have to write publications. You have to share your work with other people. Make PowerPoint presentations and write journal articles or books or whatever. So it’s a cycle that literacy influences the things we do, including the things we do in science.
Eric Cross (08:31):
Now to get in maybe some data, if you were trying to convince someone that like this happy marriage can exist, what would be like your number one piece of evidence to support this, this back and forth of supporting each other?
Douglas Fisher (08:44):
Awesome. So the quote I’ll often say — and this is from studies from more than two decades ago now — but in general, in high school science, students are introduced to 3000 unfamiliar words, 3000. Each year! Because there are words that are used in a scientific way that are used commonly in other places. And there are discipline-specific words. So 3000 words a year in high school science. The Spanish 1 textbook only has 1500 words in it. So science teachers have double the academic-language vocabulary demand that a typical introductory world-language class has. So just the vocabulary alone should say to us, literacy is gonna be important if you’re gonna learn science. And if you don’t understand these technical words, and you don’t understand the way science uses this particular word in this particular way… . When you say the word “process,” it means something very specific In science. “Division” — cellular division is not the way we think about it in mathematics; there’s a similar concept, but cellular division is different than dividing numbers. And those are words that get used in multiple areas. Then you have all these technical terms that you have to be able to use, to understand the concepts. To share the concepts. To talk to other people. Whether you’re in, you know, fifth grade and talking science, or you’re a university professor, there’s a shared language, appropriate for our grade level, that we have shared meanings of.
Eric Cross (10:22):
And we’re essentially … what I’m hearing you say is … most of the people that are listening to this are science teachers. We’re we’re also language teachers. In a sense.
Douglas Fisher (10:29):
So my frustration is when people say, “Every teacher’s a teacher of reading.” And I don’t like that. I’ve written against that phrase. I don’t think all teachers are teachers of reading, any more than all teachers are teachers of chemistry. Or all teachers are teachers of algebra. But what I will say is the human brain learns through language. And all of us — every teacher that I’ve ever met understands that language is important in my class. If my students don’t have strong listening skills and speaking skills; reading, writing, and viewing skills; I’m gonna have a hard time getting them to learn things. If I can help them grow their speaking, listening, reading, writing, and viewing in my content area, I’m gonna do a service for my learning of my subject and also their more broad literacy development.
Eric Cross (11:16):
- So, at a high level, what does it look like to integrate science and literacy? We’ve done education for the last, what, hundred years?
Douglas Fisher (11:24):
Mm-hmm. <affirmative>
Eric Cross (11:25):
—kind of pretty similarly, right? Kind of siloed way. What does this look like at the 30,000-foot level? You’re a professor, department chair. Run schools. Speak everywhere. Like, when you think about this from that high level, what does it look like?
Douglas Fisher (11:39):
A high level? Every time I meet with students in a science class, you know, biology or fifth grade or whatever? They should be reading, they should be writing, they should be speaking and listening. Every class. So what print do you want them to access? And it can be a primary source document, it can be an article, it can be from a textbook. Are they reading something? Are they writing to you? Because writing is thinking. If they are writing, they are thinking. As soon as their brain goes somewhere else, they stop writing. The pen won’t move or the fingers don’t type. And then speaking and listening, of course, is the dynamic of our classes. So every day we should see some amount of reading, writing, speaking, and listening, viewing in our classes. That’s at a high level. There are some generic things that seem to work across the literacy. So, learning how to take notes. Focusing on vocabulary. Using graphic organizers. These are generic things that as educators we can use in our classes. Then there’s more specialized things. So, scientists and science teachers think differently than historians and literary critics and art critics. So scientists, if you look at the disciplinary literacy work, there’s a whole body of research where they interview and study high-end experts in their field: chemistry, physics, biology, et cetera. And there are some characteristics that were more disciplined, specific. Scientists like cause and effect relationships. They look for them when they’re reading. They like sourcing information. “Where this come from?” “What’s the history of this idea?” Scientists have a long view in terms of time. Historians have a shorter view of time. English teachers have even shorter view of time. Scientists tend to think in long periods of time. And so all of that influences how a scientist reads and how we should apprentice young people after they get past the generic “I know how to take notes. I know how to study my vocabulary. I know how to do summary writing for my teacher in my notebooks and things,” there’s some generic tools. Once we get past those, we need to be looking at specifically how do people in science use literacy.
Eric Cross (13:52):
I’ve never had my thought process of reading deconstructed just now, but we just described how scientists read. I was like, “Yeah, that’s pretty much how I read, right there.” I also like how you said how we should apprentice young people. And I feel like you as the literacy guy, you chose that word very specifically, as far as apprenticing young people. That is a view, I think, that’s really important to hold. ‘Cause that’s what we’re doing essentially … is, if we’re doing what we should be doing, we are apprenticing these young people.
Douglas Fisher (14:18):
Yes.
Eric Cross (14:18):
And helping them develop. Now, let’s imagine there’s a listener out there and they’re interested in getting better at integrating science and literacy instruction. They want to start somewhere. Before we dive in, do you have any initial words of encouragement for the person who’s like, “Everything is like a priority right now,” in their classroom or in their world?
Douglas Fisher (14:37):
Yeah. So I’ll talk about elementary for just a moment. When we’re reading informational texts in our literacy block, we should be reading information that is aligned to what kids need to learn in science and history in, in that grade level. Why are we reading things that are gonna be in conflict with what they’re gonna learn in science later that day in fourth grade, for example? So when we look at our standards, our expectations, what is it that third graders need to know in history, science, mathematics, language arts? And when we’re reading text and we’re learning to apply our reading strategies during our literacy block, why aren’t we reading topics that build our background knowledge for our science time? So we’re seeing some synergy there. We should be looking at life cycles in grades that are appropriate for life cycles and knowing there’s more to life cycles than the frog and the plant or the seed. There are all kinds of life cycles. And we call ’em life cycles for a reason. That’s a general concept. Now in science, we’re looking at this particular lifecycle right now. And so that’s a high level. If we could get more connection to the content standards during our literacy blocks, it would be very good. When we talk about the time at which we call “science” in the day, in more of the K–8 continuum, the science needs to include some primary source documents. Some real things that students are reading. Read about a scientist; read about a scientist’s discovery; read about what they discovered. So that we’re building our background knowledge. So when we go to do things, activities, labs, simulations, we have background knowledge and we understand what we’re experiencing. It can’t be like—I watched this awesome lesson on lenses and the teacher had all these different lenses in the room and the students came in and they were brand new. They don’t know anything. They were picking ’em up. They’re exploring them. They’re trying to figure out, and they’re trying to come up with theories about what this is and how it works. And then the teacher gave them a reading, a short reading, on refraction of light. And they read this thing. And the clarity that they had about what these lenses must do, well! All of a sudden they’re putting them up to the lights! They’re asking if they can go get the lights out of the storage unit! ‘Cause there’s — and they’re shining different lights through the lenses to see what happens to the light. Because that little bit of reading turned some focus on for the students. And it allowed them to take what I’m thinking about, what I’m trying to figure out, how this thing works in another direction. That’s the power of using literacy in our classes.
Eric Cross (17:20):
And what I’m hearing essentially is transfer across disciplines, across content areas, ultimately. And in an elementary school classroom, would it be fair to say, probably the teacher has more autonomy to be able to do that, since they’re teaching all the subjects? But secondary, logistically, planning and those types of things … from what you’ve seen, is it fair to say this kind of needs to be like a top-down, full vertical alignment, to teach like this?
Douglas Fisher (17:45):
I think that would be awesome to do that. But if I’m a sixth grade English Language Arts teacher and I’m working with my sixth grade science teacher, the conversation should be, “What units are you teaching?” Because I’m choosing informational text. My job is to teach them how to find central ideas. My job is to teach them how to find the details in the text. My job is to have them make a claim and support that claim with evidence. The stuff I use is generic. Yes, we do read some literature and some narratives, but we also read about 50% of the text in English around informational text. So if I can help you and accomplish my standards as well, fantastic. So let’s have this conversation and say, “Oh, this is what you’re teaching in science in the next three weeks? I’m gonna choose some texts and we’re gonna analyze ’em for central idea. We’re gonna analyze ’em for details. We’re gonna, for mood or tone or whatever that we’re teaching. And by the way, I’m building background knowledge. So when they come to you, they know some stuff about what you’re going to be teaching next.” So I don’t think it’s impossible to say teams of teachers could come together and say, “What do we believe that our students need to know and learn and be able to do? And then how do we choose things that are gonna help them accomplish exactly that?”
Eric Cross (19:01):
And that’s empowering. Because that’s one thing that we can control maybe is this East-West, peer-to-peer, different content areas. A system may not be able to change as quickly, but I can definitely go talk to my English team or math team and check in and kind of see, “Hey, where do we have overlap in that?” And I know the times that I’ve accidentally had overlap with the teams, it’s super-exciting. And the students have been more bought in! Because it’s like, we’ve done something on the human microbiome and we’ve talked about genetics and all these different things, and then when they read The Giver, or they read some book about genetics, they have all this knowledge. And they’re excited. And they talk about colorblindness or they come to my class and they’re like, “Hey, we read about this!” It’s almost like they saw a magic trick, the fact that these things linked up. And the engagement has been so much higher when it’s the same content in different classes, but through different lenses. At least, that’s what I’ve seen in my years of teaching.
Douglas Fisher (19:54):
I saw a lesson on space junk that was so cool. Middle-school students learning space junk. And the history teacher had a part of it, science teacher had a part of it, English Language Arts teacher had a part of it. And these students, I mean, you watch them look up all the time, ’cause there’s space junk up there. Where’d it come from? Why is it there? What are the politics of this? How do we clean it up? I mean, it was just so interesting to watch them when the teachers came together. And the teachers met their standards in this couple-week-long space-junk exploration. Investigation was met. Politics was met. All these different things. Economy. You know, how much does it cost to clean up this problem? So there’s really cool opportunities when teachers come together and realize we can work together and improve the literacy and learning of our students.
Eric Cross (20:50):
Absolutely. So before this recording, we picked your brain a bit. And I know that there were three specific strategy areas that you wanted to touch on. And one of those — which is kind of coming back to the 3000-words language teachers — was vocabulary. So what are the opportunities that you see, as far as the way of educators to approach vocabulary? Because, you know, there’s a lot. We got a lot of it. The 3000 words.
Douglas Fisher (21:14):
Yeah. There’s a lot of it. So the worry is, we make a vocabulary list and have students look up the words in definitional kinds of things. That’s not really gonna help. Students need to be using the words. They need to be using the words in their conversations, in their writing, in how they think about your content in science. So vocabulary is a huge predictor of whether or not you understand things. Vocabulary is also a pretty good predictor if you can read on grade level. So when we think about vocabulary, there’s something called word solving. You show students a piece of text and you’re reading it, you’re sharing your thinking, and you say, “Oh, here’s a context clue!” Or “I know this prefix or suffix or root!” And in science, a lot of the words are prefixed, suffixed, or root words. We tend to add things together with a lot of prefixes and suffixes and have roots and bases in science. So we can help students think about, “Oh, what does geo- mean? We already know what geo- means here. It means the same thing in this word. Let’s apply that knowledge.” So word solving is part of it, showing students how we think about words that we might not know. The second is more direct instruction of vocabulary. As students encounter the words, we work on what it means, how we say it. We practice it a few times. The process is called orthographic mapping. It’s kind of a scientific idea here. But you have the sound and the recognition of by-the-word, by sight, and what it means. And your brain starts to automatically recognize that word in the future. So I don’t have to slow down, disrupt my fluency, and try to figure out what the word is saying. ‘Cause I’ve seen it enough. I’ve heard it pronounced enough, I’ve pronounced it enough, and I know what it means. So teachers should be saying, “What words in sixth grade science, what words in third grade science, do my students really need to know?” And I’m gonna have them encounter those words over and over. I’m gonna have them use the words. I’m gonna have them see the words. I’m gonna have them say the words. I’m gonna say the word and we’re gonna be over and over with these terms, so that students incorporate them into their normal view of, “These are the things I know about the world.” By the way, when they go to read that next thing, and they understand “geology,” you know, for sixth graders, for example, they know how to say it. They don’t stumble on it. And it activates a whole bunch of memories in their brains. “This is what geology is.” There are branches of geology, there’s physical geology, there’s all this thinking that activates as they read.
Eric Cross (23:35):
There was a practice that I participated in and am trying to incorporate — I don’t know what the name of it is. But essentially what happened was we were dissecting a flower. And the instructor had us name parts of the flower. But we got to come up with our own names for it.
Douglas Fisher (23:49):
Ah.
Eric Cross (23:50):
So, for instance, the stamen we call “the fuzzy Cheeto.” And we all used our own words and then everything was legitimized. And so we went through and learned the whole activity using our own vocab words. But then, in the end, after we presented and talked about it, then the words, the actual academic language was attached to our word. And we were able to say, “OK, the fuzzy Cheeto is the stamen,” and this, this, this, and this. But it was such an interesting practice, because it kind of legitimized all of our definitions. But we weren’t stumbling on these long Latin terms and things like that. Is there a name for that? Or. … ?
Douglas Fisher (24:29):
Yes. I don’t know the name for that. I think it’s really smart. So here’s what I would say about that, is: we don’t learn words, we learn concepts. Words are labels for our concepts. So what that teacher did for you was allow you to develop concept, a concept knowledge. “There’s a part of this plant, it goes like this, we’re gonna call it fuzzy Cheeto. Now I have this concept. And look, it occurred in all these plants. And those people called it that and that other group called it that. We called it a fuzzy Cheeto. Here’s the part of it.” And then the concept is in your brains. And the teacher said, “It’s really called stamen.” And it’s an instant transfer, because you already had the concept. What we often see is students are trying to learn a really hard academic word and the concept for the word at the same time. And so it slows down the whole process. And there’s higher levels of forgetting. Because human beings, we don’t learn words; we learn concepts. If you don’t have the concept, if I gave you a word out of the blue that you’ve never seen, never heard, and a week from now I asked you to remember it, you probably would not, because it didn’t register. It wasn’t part of your schema. You didn’t have a way to organize the information. You don’t have a concept. So that teacher? It’s a great idea. Got you to develop concept knowledge. And then said, “Here’s a real label for it: What some other people called it when they had the chance to come up with their own names.”
Eric Cross (25:50):
Shout out to my teacher, who was—
Douglas Fisher (25:51):
Right.
Eric Cross (25:52):
It was learned then. It was a great practice. And the fact that you’re right, like, I just mean from my own personal experience, I agree that learning concepts versus complicated words. And it’s interesting that you said higher levels of forgetfulness, you know. And you often hear that complaint about it: “Students forget! Students forget!” But this complex topic and this complex word that’s new to me, and I have to remember both of those things.
Douglas Fisher (26:12):
That’s right.
Eric Cross (26:13):
And the other neat thing that it did, is it actually honored the background and like the founts of knowledge of all the different groups in the classroom. You just said something about “this group called it this and this group called it this,” and so by letting different groups share all of those names, now we’re starting to build these kind of interesting connections. That’s at least what I remember experiencing. And so this, even this practice of this approach is very layered, beyond just kind of generating new knowledge of things. So I appreciate that aspect of it. Now another area that you mentioned was complex text.
Douglas Fisher (26:41):
Yeah.
Eric Cross (26:42):
And how we can get students into complex text. So what can we do there?
Douglas Fisher (26:46):
I think science is an ideal place to get students reading things that are hard for them. And I do believe that some parts of school should be a struggle. Not all day, every day. But there should be doses of struggle, which are good for our brains. And these complex pieces of texts that don’t give up their meanings easily allow students to go back and reread the text and maybe mark the text and talk to peers about the text and answer questions with their groups. And the whole point of complex text is to say, “We persevere through it. We may not understand it fully on our first read. But we go back and we might underline, we might highlight. We might write some margin notes. Our teacher might say, ‘What did this author mean here?’ And we go back and look at that part and we take it apart. What do we think about that? And we talk to each other. It’s showing that when we read things, we work to understand. We work through our thinking, often in the presence of other people. And our understanding grows as we go into the text over and over and over again.” So I said geology earlier. There’s about a two-page article on “what is geology” that sixth graders often read. And some kids find it super boring. It’s a once-read, “OK, geology, I don’t really understand it. There’s a bunch of words in here that I don’t understand.” But if you go back to it a few times and you start taking apart, “What are the branches of geology? Oh, I’m gonna go reread that.” How are these two branches related to each other?” “What are the subtypes of each branch of geology?” “How do geologists do their work?” You start asking questions where students are going back into the text. You spend a little bit of time. Now, the introduction to geology, the students know so much more. So whatever you do next— video experiments, whatever—they have a frame of reference, because of that deep, complex read. It’s probably better than simply telling them, “Here’s the information.”
Eric Cross (28:45):
Right. And I even feel like as an educator, when I reflect on my own learning in the classroom, and then looking at it through the perspective of an educator <laugh>, you find this difference between how you were taught and then what the data says good teaching is.
Douglas Fisher (28:59):
Mm-hmm. <affirmative> mm-hmm. <affirmative>.
Eric Cross (29:00):
It’s so easy to slide back into how you were taught!
Douglas Fisher (29:02):
Yeah.
Eric Cross (29:02):
Even though, you know, you mentally assent to, “This is the best way. This is the data shows.” And you find yourself kind of sliding back at times.
Douglas Fisher (29:10):
Yep. And there’s good evidence to support what you just said, that most people teach the way they experienced school. And it is very hard to change that. And people have studied this. And it’s very hard to change that. Because it worked for us. And we have an n of 1, and it worked for us. Now, remember, there were a whole bunch of other kids in the class that it may not have worked for. And we chose to be in school the rest of our lives, and some of your peers did not choose to be in school the rest of their lives. In fact, some of them hated school and found no redeeming qualities of their experience. So just because it worked for us in a case of one, n of 1, doesn’t mean it worked for all of the kids, or even the majority of them.
Eric Cross (29:57):
Very well said. It’s that, what is that, the survivor bias? Survivorship bias? Where you were the one that made it. But you don’t think about all the other folks. ‘Cause we’re thinking about ourselves.
Douglas Fisher (30:05):
That’s right.
Eric Cross (30:06):
Great case for empathy too, is thinking about the people left and right. Because my friends are like, “I hated science.” And I say, “Who hurt you? Like, what did they do? It’s so amazing, so much fun!”
Douglas Fisher (30:16):
“What happened to you? Science is the coolest. Right? It’s so amazing!”
Eric Cross (30:21):
But I also had a unique experience in seventh grade with my teacher who did some of these things, and made it accessible for so many of us, in opening opportunities that I wouldn’t have had otherwise. But you’re absolutely right. That was my story. That wasn’t the story of everybody that was around me. And I think that’s really important. Now, I know this is also a big one for you, but I wanna talk about writing. What are the opportunities that you see in terms of writing specifically?
Douglas Fisher (30:51):
So would love it if science teachers had short and longer writing tasks in the science time. Of course, you can integrate some of the science writing, the longer ones, in the English language arts time, especially if you’re the elementary teacher and you can have control of the whole day. But I said this earlier; I’ll say it again. Writing is thinking. While you are writing, there’s nothing else you can do but think about what you are writing. Your brain cannot do something else. So if a science teacher wants to know, do their students really understand the concepts? Have them write. Now some of the shorter ones, I like something called “given word” or “generative sentences”: “I’m gonna give you a word: CELL. C-e-l-l. We’re in science. I want you to write the word ‘cell,’ c-e-l-l, in the third position of a sentence. So it’s gonna go word, word, cell, and then more words.” You could also say, “I want the sentence longer than seven words,” or whatever. But the key is, I’m telling you where I want the word. You will know instantly if your students have a sense of what the word “cell” means in the context of science. If they write “my cell phone,” they don’t get it. If they write about spreadsheet cells or jail cells or whatever, they didn’t get it. But if they talk to you about plant cells and animal cells and the components of those cells, and then once they have that sentence down, you can say to them, “Now write three or four more sentences that connect to that sentence.” It’s super simple. So whatever concepts you’re teaching, put ’em in a specific position. Now you don’t have to only put it in the third position. You can say the first position, the fifth position, the fourth position. But it forces them to think about what they know about the word and then how to construct a sentence for you. That’s a very simple way to get some writing from your students that helps you think about what they understand. Other kinds of writing, you can have quick writes, you can have exit-slip writes. There’s something in the research space called the muddiest part, where halfway through the lesson you have them write so far what has been the least understood or the most confusing part of this lesson. And they do a quick write, right there, at the muddiest part. And as a teacher, you flip through these and you start to say, “Oh, these are the points that are confusing to my students.” So if 80% of them all have the same thing, I gotta reteach that. If these five got, “This is the muddiest part,” If these five thought, “This is the muddiest part,” these seven, “I thought this was the muddiest part,” what do I need to do? Because it’s gonna be hard to move forward if this is their area of confusion. There are also all kinds of writing prompts that have a little bit longer. My favorite one is RAFT. What’s your Role? Who’s your Audience? What’s the Format? And what’s the Topic we’re writing about? Super flexible writing prompt. When you teach something, we don’t want students to only think they write to their teacher. So your role is an atom. You are writing to the other atoms. What do you wanna write about? What’s the topic? What’s the format of it? Is it a love letter? Is it a text message? Is it … so we, we mix it up with students in saying, how do they show some knowledge through a prompt that we give them? And then of course, longer pieces as they get older. More opinion pieces through fifth grade. More claims and arguments starting in sixth grade. So that they’re starting to see, “I have to use the evidence from things I’ve learned, read, listened to, watched, and construct something: an opinion, an argument where I back it up with reasons or evidence.” And those longer pieces, you know, less frequently. The shorter pieces, pretty regularly. So the teacher sees the thinking of the students.
Eric Cross (34:29):
When you were speaking about these really creative writing prompts, there were specific students coming into mind, that were coming into mind … they’re, they’re great science students, but they also have this really strong artsy side drawing, creative writing, and things like that. And when you said something about atoms talking to each other, it elicited, in my brain, certain students that would really love this aspect of creativity in the sciences. And it’s not how we’re typically trained as science teachers, to kind of incorporate this, like you said. A book of props. But I’m imagining, like, as a science teacher, if I took this, this would be a great way to reach more students to be able to show what they know, in a way that might resonate with their own intrinsic “Oh, I get to write creatively!” So I was kind of writing furiously as you were sharing all that information there.
Douglas Fisher (35:12):
So here, I’ll give you another example for elementary people. Again, with RAFT. There’s a book called Water Dance. It’s a pretty popular book for elementary teachers. It’s really about the life cycle of water. For example, you are a single drop of water. You are writing to the land. The format is a letter. And you’re explaining your journey. Now, if they can do this, they’re essentially explaining to you the cycle of water. But you got it in a way that people are now, “Oh, I’m a drop of water. So it’s me. My perspective. Where do I go from? Where do I start?” Because you can start anywhere in the cycle, right? My drop could have started in the clouds. My drop could have started in the ground. My drop could have started in the lake. But it has to show you the journey. So there are many ways of showing you the right answers.
Eric Cross (36:02):
And that’s using the RAFT protocol.
Douglas Fisher (36:04):
That’s RAFT: Role, Audience, Format, Topic. It’s been around 20 or 30 years.
Eric Cross (36:09):
You just gave the name to something a teacher shared in our podcast community, Science Connections: The Community, on Facebook. Teacher shared a Google slide deck and on it were just three slides. And the role that the student had to have is they had to show, then tell, the story of a journey of a piece of salmon being eaten, a piece of starch from pasta being eaten, and then an air molecule in a child’s bedroom. And they had to give the path of travel and the experience from the mouth and then breaking down into protein and all those kinds of things. And this teacher shared it and I wish I knew the teacher’s name because I wanna give ’em credit, but they shared it. And so I used it with my students and then had ’em read aloud their stories and dramatize it. And they were so into it!
Douglas Fisher (36:49):
So cool.
Eric Cross (36:50):
But through it, I was able to see that they understood different parts of the body. They understood cell respiration. The whole thing. And it was fun! To watch them get so into this creative writing. And now I know the name of it. That’s been 30 years they were using RAFT. So you just talked a bit about complex texts and writing. And before we go, I wanted to circle back to something that you said, because I think it’s important, and if you could elaborate on it a little bit, about the value of struggle. Can you talk more about that?
Douglas Fisher (37:21):
Sure. I do believe in a lot of the U.S. we’re in an anti-struggle era of education. And it predates Covid. I think it made it worse during Covid. We front load too much. We pre-teach too much. We reduce struggle. We quote, “over-differentiate” for students. And there’s value in struggle. The phrase, “productive struggle” — if you haven’t heard it, Google productive struggle — it’s an interesting concept, that we actually learn more when we engage in this productive struggle. Now, productive struggle originally came from the math world, and it was this idea that it’s worth struggling through things to learn from it, that you’re likely to get it wrong, and then there was productive success. And there are times when we want students to experience success and we make sure we put things in place for productive success. But there are times where we want them to struggle through a concept. ‘Cause it feels pretty amazing when you get on the other side, when you know you struggled and you get to the other side. If you think about the things, listeners, think about the things in your life where you struggled through it and you are most proud of what you accomplished. I want students to have that. I don’t wanna eliminate scaffolding, eliminate differentiation. But I do want some regular doses of struggle. So if you look at the scaffolding, we have a couple choices. We have front-end scaffolds, distributed scaffolds, and back-end scaffolds. Right now we mostly use front-end scaffolds: We pre-teach, we tell students words in advance, that kind of stuff. But what if we refrained from only using front-end scaffolds, and we use more distributed scaffolds, when they encounter. So there’s a difference between “just in case” and “just in time” support for students. So we tend to plan on the “in advance, here are all the things we’re gonna do to remove the struggle before students encounter the struggle.” What if instead we said, “Let them encounter some struggle. Here’s the supports we’re gonna provide. We’re gonna watch; we’re gonna remove those scaffolds, and allow them to have an experience of success, where they realize, ‘I did it. I got it.’” Every science teacher I’ve ever worked with, when they do an experiment or a lab or simulation, they are looking for productive struggle. They don’t tell the answers in advance. They don’t tell if the answers are right. That’s your data. What does your data tell you? I mean, this is what you do. But then the other part of your day when you move into, like, reading, you don’t do that. You fall into the trap of removing struggle. And so allow them to grapple with ideas. Allow them to wonder what words mean. Allow them to say, “I’m not getting this, teacher! It’s really frustrating!” And you say, “Yeah, this is really hard. This is why we’re doing it at school. ‘Cause it’s really hard. If it was easy, I’d have you do it at home. But we’re doing it here, ’cause it’s really hard and it’s OK not to get it at first.” And create a place where errors are seen as opportunities to learn, and struggling through ideas and clarifying your own thinking and arguing with other people to reach an agreement or reach a place where we agree to disagree is part of the power of learning.
Eric Cross (40:38):
There’s a teacher, who I took this from. My master teacher when I was student teaching. And she said that there’s no such thing as failure in science, just data. And I took that same mantra. And I resonate with what you said about how science teachers, all of us, hold onto that productive struggle, because it’s part of being a scientist. It’s part of the experiments. That genuine “aha” moment. Or it didn’t work out? That’s great! That’s totally fine! Let’s write about it and let’s take photos and let’s publish it and let’s be scientists. That’s totally true. As we wrap up, Dr. Fisher, is there any final message that you have to listeners about bringing science and literacy together? I know you speak everywhere, but for everyone that’s listening, if you can put out your encouragement or message or suggestion … you’ve given so many great tips and practical applications. But, any final thoughts on the subject?
Douglas Fisher (41:32):
I think many science teachers are intimidated because they think they have to be reading teachers. And there’s a knowledge base to reading. And some teachers are reading teachers and science teachers, and I don’t wanna dismiss that. But it’s not that you have to become a reading specialist to integrate literacy into science. It’s how our brains work. And so as you think about the way in which you are learning and the ways in which you want your students to learn, what role does language play? What role does speaking, listening, reading, writing, viewing, play in your class? And then provide opportunities for students to do those five things each time you meet with them.
Eric Cross (42:12):
Dr. Fisher, thank you so much for being here and for your encouragement, and sharing your wisdom and experience. And then personally serving my city, here in San Diego, and my students, when they make it to your high school and ultimately the alma mater of San Diego State University.
Douglas Fisher (42:30):
That’s right.
Eric Cross (42:31):
Yeah. We really, really appreciate you in serving all kids and lifting the bar and making things more equitable for all students. And encouraging teachers. So thank you.
Douglas Fisher (42:39):
Thank you very much.
Eric Cross (42:42):
Thanks so much for listening to my conversation with Dr. Douglas Fisher, Professor and Chair of Educational Leadership at San Diego State University. Check out the show notes for links to some of Doug’s work, including the book he co-authored titled Reading and Writing in Science: Tools to Develop Disciplinary Literacy. Please remember to subscribe to Science Connections so that you can catch every episode in this exciting third season. And while you’re there, we’d really appreciate it if you can leave us a review. It’ll help more listeners to find the show. Also, if you haven’t already, please be sure to join our Facebook group, Science Connections: The Community. Next time on the show, we’re going to continue exploring the happy marriage between science and literacy instruction.
Speaker (43:26):
I had this moment of realization I felt a few months ago: I’m like, if I don’t teach them how to use the AI as a tool, as a collaborator, then they’re gonna graduate into a world where they lose out to people who do know how to do that.
Eric Cross (43:39):
That’s next time on Science Connections. Thanks so much for listening.
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Meet the guest
Douglas Fisher, Ph.D., is professor and chair of Educational Leadership at San Diego State University and a leader at Health Sciences High & Middle College having been an early intervention teacher and elementary school educator. He is the recipient of an International Reading Association William S. Grey citation of merit, an Exemplary Leader award from the Conference on English Leadership of NCTE, as well as a Christa McAuliffe award for excellence in teacher education. He has published numerous articles on reading and literacy, differentiated instruction, and curriculum design as well as books, such as The Restorative Practices Playbook, PLC+: Better Decisions and Greater Impact by Design, Building Equity, and Better Learning Through Structured Teaching.
About Science Connections
Welcome to Science Connections! Science is changing before our eyes, now more than ever. So…how do we help kids figure that out? We will bring on educators, scientists, and more to discuss the importance of high-quality science instruction. In this episode, hear from our host Eric Cross about his work engaging students as a K-8 science teacher.
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S5-02. Uncovering the causes of math anxiety
We’re continuing our season theme of math anxiety, going beyond the basics, diving deeper into what causes it, and how we can help students move forward. In this episode, we talk to Dr. Erin Maloney from the University of Ottawa to better understand what’s actually happening in the brain when a person experiences math anxiety, and how we can take steps to shift student mindsets in a positive direction.
Listen now and don’t forget to grab your MTL study guide to track your learning and make the most of this episode!
Enjoy this episode and explore more from Math Teacher Lounge by visiting our main page.
Dr. Erin Maloney (00:00):
It’s the anxiety itself in many ways that can cause people to underperform.
Bethany Lockhart Johnson (00:06):
Welcome back to Math Teacher Lounge. I’m Bethany Lockhart Johnson.
Dan Meyer (00:10):
And I’m Dan Meyer.
Bethany Lockhart Johnson (00:11):
This is episode two of our new season, all about math anxiety. Who has it? What is it? What do we do about it?
Dan Meyer (00:20):
I’m learning so much, learning a ton.
Bethany Lockhart Johnson (00:22):
I loved our first conversation with Dr. Gerardo Ramirez, episode one, our first episode of the season. Really, our goal with that conversation was just to—we need to talk about the basics of it, for reals. Like, what is math anxiety?
Dan Meyer (00:36):
What is it? How do you measure it? How’s it defined? Super-helpful stuff.
Bethany Lockhart Johnson (00:40):
There’s not only one way that it’s measured. But it’s like, in active research right now, how are folks making sense of it? And I think Dr. Ramirez did such a fantastic job of sharing that with our listeners. And I learned a lot. You learned a lot, Dan?
Dan Meyer (00:56):
I did. And I’m also super-excited to take that knowledge that we have developed together and go and build on top of it and keep on climbing up up the mountain here, and learn more about math anxiety. Which is why we’re super-excited to have a guest on, Dr. Maloney, who is going to help us learn more—especially about what happens to the brain when it’s experiencing math anxiety. There’s some really complex stuff that happens there, including the role of parents and educators in creating and resolving math anxiety. And I think we’ll also learn that the whole situation is a bit of a hot mess. And we’ll try to make it a little bit less messy together.
Bethany Lockhart Johnson (01:34):
Little bit less messy. Dan, if we do nothing else, can we make it a little less messy?
Dan Meyer (01:41):
I sometimes prefer more mess, but in this case I prefer less. So.
Bethany Lockhart Johnson (01:45):
I have a two-year-old, so everything is a mess.
Dan Meyer (01:47):
Your life is mess. Yes. <laugh> Right. Well, I’m excited for you folks to hear this. It was a delightful conversation, so yeah, tune in. We are joined by Dr. Erin Maloney.
Bethany Lockhart Johnson (01:56):
Let’s go. We are joined by Dr. Erin Maloney, associate professor in the School of Psychology at the University of Ottawa, where she directs the Cognition and Emotion Laboratory, as well as serving as the Canada Research Chair in Academic Achievement and Well-being. Welcome to the show, Dr. Maloney. We’re so excited to have you in the Lounge.
Dr. Erin Maloney (02:20):
Yeah, thank you so much for having me. This is fantastic.
Bethany Lockhart Johnson (02:24):
So our last season was all about math and joy. And even when I read your title, I felt more joyful. Like, somebody is thinking about academic achievement, but with well-being in mind. I love it.
Dr. Erin Maloney (02:39):
Aw, thank you.
Dan Meyer (02:40):
Cognition and emotion!
Bethany Lockhart Johnson (02:42):
E-mo-tion!
Dr. Erin Maloney (02:43):
I don’t think they can be separate. I think that you have to think about them together, ’cause they’re so intricately connected.
Dan Meyer (02:49):
Love that. People try, but we love that. Yeah. That’s our vibe here, too.
Bethany Lockhart Johnson (02:52):
People try. That was a big problem with my math anxiety. They just wanted…there was no room for my emotion. They’re like, stop weeping at your desk—
Dan Meyer (03:00):
It’s rearranging neurons….
Bethany Lockhart Johnson (03:01):
—you’re distracting the other children. So would you mind telling us the story of how you even got interested in this topic? You know, when you tell people that you study math anxiety—or, actually, I don’t know how you describe it to them; I’m hopeful you bring in that well-being part—but how did you get here? What do you, what do you, what do you…yeah, tell us! We love it!
Dr. Erin Maloney (03:23):
<laugh> I feel like what you’re actually asking is, “How did you make life choices that got you to here?” <Laugh>
Bethany Lockhart Johnson (03:29):
Justify your life choices! Ready? Go!
Dr. Erin Maloney (03:32):
<laugh> Whoo. OK. So, all right. So we often, in psychology, we joke that instead of doing research, we do “me-search.” And that’s, that’s admittedly true in my case. I was a student who absolutely loved math up until about eighth grade, and then something changed, and all of a sudden I was terrified of math and I had absolutely no sense of self-efficacy in it. Despite trying really hard, I was extremely anxious about it. And so I initially, I set out…my parents were completely convinced that I was absolutely capable of doing mathematics and that I was getting in my own way. And when I went to university, I decided to prove them wrong. So I set out to prove that some people just can’t do math, and that’s the end of it. And, you know, 20 plus years later, my parents were right. And it turns out that many people—well, I would argue virtually everyone—can do math. And that if you are really anxious about it, it can get in the way. And interestingly, you know, in, in the years that we’ve been doing this research, there’s really good strategies that can be used—that hopefully we get a chance to chat about—that can really help reduce the amount of anxiety that students are experiencing. But I really did set out, like the bold teenager that I was, to prove my parents wrong. And that backfired <laugh>. So I know it’s kind of a strange answer, but it’s the truth. So I was really interested in understanding why it was some people just could not do math.
Dan Meyer (05:10):
That makes two for two so far, on guests for this season who did a version of me-search. And I feel like this is pretty common for a lot of researchers. Like, I wanna figure out…my experience as a teacher, the part where you, I think, diverge from a lot of people I knew in grad school, myself included, is that you actually let counter evidence change your perspective on things. Whereas I feel like a lot of us go in: “I know this is true and I’m gonna gather data!” and lo and behold, I’m true! But only now, with the research TM, you know, trademarked research, attached to it. So that’s, really exciting. Thanks for sharing that.
Dr. Erin Maloney (05:43):
No, you’re welcome.
Bethany Lockhart Johnson (05:44):
But don’t people say that the more personal you get, the more universal it is? Right? So if you go and get your doctorate about something that you think is just your experience or in your brain, then people are gonna be gonna be like, “Wait a second; you think that too?” “Wait, that math anxiety isn’t just you?” I don’t know, it sounds like a pretty great path to me. When you tell folks that you study math anxiety or when you’re speaking to folks about your research, do you find that there is a lot of folks who relate to what you’re studying? Or how does that conversation typically go?
Dr. Erin Maloney (06:20):
Yeah, so it is I think an extremely relatable topic. Not in the sense that everyone experiences anxiety about math, but everyone seems to know somebody who’s really anxious about math. Or everyone’s at least aware of the stereotype that like some people are math people and some people aren’t, and that’s just the way it is. So it feels like everyone has feelings about math and everyone seems very happy to share those feelings. So one thing I’ve always found really interesting, and actually, so I, I know you mentioned that you had Gerardo on recently. Gerardo and I have had really interesting conversations about how people are really quick to tell you that they hate math and they can’t do math, and they’re anxious about math. And I’ve yet to have anyone ever tell me they hate reading, they can’t read, they’re really anxious about reading as an adult. So for some reason math seems really different. And in that sense people always seem to be pretty excited to talk about their feelings towards math.
Dan Meyer (07:23):
Yeah, definitely. Been on an airplane or two myself and had those conversations. You know, people asking to be reseated because they found out that I do math for a living or whatever. Or just unburdening themselves, for sure. I’m super-curious: I think that the fact that you are doing the me-search is reason enough to want to dedicate your life to this study. But I am curious: If you were gonna justify to someone else, why is math anxiety important to study? What are its consequences, even outside of math education? What would you say to that?
Dr. Erin Maloney (07:57):
So I think it’s probably not hard to convince people that success in math is important, right? So we know that children who start elementary school behind in mathematics tend to stay behind in mathematics, unless they have any kind of very targeted intervention. We know that children who do worse in mathematics throughout K to 12 education in general get lower-paying jobs when they’re older. We also know that when they do worse than mathematics relative to their peers, there’s fewer jobs that are open to them, relative to if they excelled in math. Right? And so I think in many ways there are really clear consequences for students who are not comfortable with math and who avoid it. But I think one of the really, really interesting things about math anxiety, and maybe part of why I’ve fallen in love with it as a research topic is that it’s the anxiety itself in many ways that can cause people to underperform. So it’s not just the case that people who are bad at math are anxious about it. It’s actually that the anxiety itself can cause you to do worse in math. And that for me is really exciting, ’cause it means that if we can change your mindset, then we can really set you on a path with several more options available to you career-wise. And I think that is really empowering.
Dan Meyer (09:18):
Hmm. Yeah, definitely. And I’d love for you to explore — your laboratory is the cognition and emotion laboratory, which I love, how you’re creating those linkages between how you feel about a thing and what your opportunities or your aptitude for learning it. I’m really curious, can you say more about the, the relationship there? How does feeling anxiety impair your ability to do mathematics?
Dr. Erin Maloney (09:41):
Yeah, so feeling anxiety, typically what you tend to experience is these negative thoughts and ruminations. So you can imagine, you’re somebody who doesn’t really love math, you’re pretty anxious about it; you know, Bethany, maybe you’ve had this kind of experience before. I’m gonna call you out on it. I’ve had it many times, where you sit down to do a math test and all of a sudden you’re not focusing on the actual math test in front of you. You’re focusing on things like the consequences of not doing well on this. Right? Or “my parents are gonna be really disappointed if I don’t pass this test,” or “my teacher is gonna think negatively negative of me,” or sometimes we see things like, “I’m a girl, girls don’t do math.” These types of stereotypes. And what happens is that those thoughts actually tie up really important cognitive resources, like, really important memory resources, that you need to do the math test. And so if you are trying to essentially do two things at once, right? You’re trying to deal with all these negative thoughts that are distracting you and you’re trying to do the math test, then you’re not going to do as well as someone who’s sitting down and doesn’t have all of these distracting thoughts to deal with. And we actually know that from research that we have in our lab right now, where we just ask people like, “Hey, when you did this math test, what kind of stuff are you thinking about?” what we find is that the people who are really anxious about math report a whole bunch of thoughts that are unrelated really to the math test, per se. It’s more about the consequences of doing poorly. And as a result of those thoughts, they actually end up doing worse.
Dan Meyer (11:14):
This has been really helpful to figure out, how the emotional state of doing math affects the ability to do math. And it’s really interesting how you’re saying that the direction of the causality can go from the emotions to the cognition. And I’m just curious then, what is the source of the bad emotions about math? Where does that come from? Is it nature? Is it nurture? Some combination? How do you see it?
Dr. Erin Maloney (11:39):
Yeah, so one, that’s a fantastic question. And there’s been a whole bunch of people all around the world that have been spending a lot of time really trying to pinpoint that down. And I think the answer is that it’s, you know, it’s complex. So most of what it’s looking like right now is that it is a combination of both. So essentially what we find is that kids who start elementary school who are a little bit behind in math—and for the question of why they’re behind, that’s also complex; it could be genetics, it could be just environmental input, before the child ever entered formal schooling kind of thing—but in essence, what we find is that kids that start school behind in mathematics, those are the children who are most likely to develop anxiety about math by the time they’re finished first grade. OK? But we also know that once they’ve developed the anxiety about math, then that’s when they get these thoughts and ruminations that kind of tie up those memory resources, that then is gonna make it harder for them to succeed in math tests. So you get into this sort of vicious cycle, right? Where maybe you start behind a little bit and then you develop the anxiety, the anxiety causes you to underperform relative to what you should be able to, so now you’re even further behind, you get more anxious because you’re not doing as well as you’d like to…but again, kind of coming back to the “Why are the children starting behind in the first place?” Some of that seems to be the role that parents are playing in the household. So some kids come from a household where parents are playing a lot more math games with them, talking about mathematical concepts on a regular basis. Maybe they have older siblings who are, you know, practicing arithmetic and, and mathematical processing in front of them. And so those kids are exposed to more math before they ever even start formal schooling. Those kids seem to do better. And then we also know that the parents’ attitudes matter a lot too. So what we find is that when parents are high in math anxiety themselves, especially when they help their children a lot with their math homework in really early ages, we find that those kids end up being more anxious about math by the end of the school year, and they also end up doing worse in mathematics. So it really does seem to be, you know, kind of a complex set of factors that have something to do with both maybe genetic predisposition to success in math and genetic predisposition to anxiety, but then also the social attitudes and stereotypes about math to which you’re exposed at home that really seem to be coming together to create this anxiety in young children.
Bethany Lockhart Johnson (14:24):
I feel like everything you’re saying is <laugh>…it makes so much sense and yet it’s so often not talked about, right? Because it’s just more like, it gets boiled down to, “Oh, they’re just not a math person,” instead of all these other factors that are at play. And I completely remember the anxiety I felt, whether it was a test or not, walking into my math classroom when I was in ninth grade. And there’s no way I was set up and ready to learn. Right? <Laugh>. And something with—we mentioned Dr. Ramirez, he was talking about validating that anxiety. If teachers validate that like, “Oh, you know what, sometimes you might feel stumped, or this might feel overwhelming.” Even the power in creating space for that in the classroom, right? And acknowledging that it doesn’t—math doesn’t have to “come easy” to you in order for you to have access or make sense, is such a powerful concept. And I love the way that you are looking at all these different factors and saying, “Hey, it’s both simple and also a lot more complicated than we’re we’re making it.” Right?
Dr. Erin Maloney (15:36):
No, and I agree with that sentiment so much. Like, I think, though—one thing I will sort of caution is that I think when teachers are validating the anxiety, or when parents are validating the anxiety, I think there’s a very fine line that needs to be walked where we need to be able to say, you know, “It’s OK to struggle with something. That’s, that is completely OK.” And as we’re, you know, as we’re working towards something that’s really valuable, right? We can, we can work hard at something and by working hard at it, we’re going to get better. And I think that type of validating is really, really important and valuable. I think what we wanna be careful of is not to say things like, “Oh, it’s OK. I also never loved math.” And, you know, “Oh, I was never a math person either.” And so even though we might be bringing comfort to the the child, I think that that’s sending the wrong message. And so sometimes it’s really well intentioned and really not great—
Bethany Lockhart Johnson (16:37):
A hundred percent.
Dr. Erin Maloney (16:38):
—in terms of the messaging. So that’s the only…so just for people listening, the only sort of caution that I would give there is that I think there’s nuances to the validating of the feelings that are important.
Bethany Lockhart Johnson (16:50):
I am so glad you said that because as a kindergarten teacher, I vividly remember—and this is as early as, you know, the kids are five years old, right?—and I remember in a parent-teacher conference, a parent saying, “Oh, I wasn’t a math person either,” or, “Oh, no, ugh.” And they were so quick, like you said, they wouldn’t say that about reading, but they were so quick to talk about their lack of natural math aptitude, right? And, and it was really interesting because you know that even if they’re not saying that specific thing at home, those attitudes are absolutely carrying over at home. And they’re absolutely carrying over to, to how they interact with their kiddo around math and around what’s happening in the conversations about math. And I felt like a lot of times my work as a teacher was also to help support parents through their own math anxiety, and help give them some new language for how they can talk about math. And that math is more than just getting to an answer quickly. Like, let’s talk about, let’s go on math walks, let’s go on number walks, what numbers are around the home? Or oh, is that bigger than this? Do you have more of this? And even those little things, I, my hope was that it was starting to shift the conversation around what math was possible in the home, particularly when you saw that it was the parents who had palpable math anxiety. Right? And how much you know that that’s gonna impact what’s happening when you sit down to do homework together.
Dr. Erin Maloney (18:22):
Yeah. And I love that you have worked to encourage parents to do that. So we do similarly. Like even from a research perspective, where I will often give talks to parents and teachers and we talk about the idea of trying to mathematize everything, right? So just the idea that math is absolutely everywhere, and you know, whether it’s a matter of playing games in the car with your kids where you’re thinking of a number and it’s “My number is higher than 42, but lower than 80, and what number do you think I might be thinking of?” And, and gradually trying to get the child to that number. Or, you know, asking questions like, “What’s your favorite even number and why?” And just little things like that that, that I think can make math fun for kids, that help—I don’t even know how to explain it, but just that idea of bringing joy into it, so it’s not always this heavy subject that kids have to come to. So we definitely try to talk to parents about the idea of, like I said, mathematizing everything. And usually it’s well-received, ’cause often parents find it empowering, right? They’re like, “Oh, well, I could do that! But like, that’s not math!” And you’re like, “No, but it is.”
Dan Meyer (19:33):
Yep.
Dr. Erin Maloney (19:34):
Like, it is! And sometimes parents will say like, “Well, I don’t know how to do fractions.” And you’re like, “OK, but how do you bake?” “Well, I don’t know! I just, like, I know how to do those fractions!” And you’re like, “OK, but that’s the starting point. Let’s work with that.” Like, let’s, you know. And I think a lot of times, it’s reminding the parents that they’re actually far more capable than what they think they are, despite the fact that maybe they struggled with math when they were younger.
Dan Meyer (19:58):
Yeah. This is so interesting. And I feel like part of the challenge around conversations about anxiety and math and how to, how to resolve it and where it comes from, is that it, like, it presupposes a single definition of math. And so, you know, we’re talking about like how to be more mindful about math. But you know, like if kids were walking every day through a treacherous street, you know, the solution might not be become more mindful about that street. It’s just like, we gotta fix the treacherous nature of the street, really. You know, I love that we’re talking also about redefining what math is, making it more playful. That feels like a super-important component here. I’d love to know more about what you know about the role of gender in all of this. Are there differences in the way boys and girls experience math anxiety and how it relates to achievement in math?
Dr. Erin Maloney (20:48):
Yeah, so, there’s really, really interesting research on gender in math anxiety. So in general, we find that girls tend to experience more anxiety about math than boys do. So one hypothesis is that it has to do with just social stereotypes that, you know, girls are, are good at reading; boys are good at math, kind of thing. So there’s some evidence to suggest that that might be playing a role. There’s other evidence to suggest as well that maybe boys actually do experience as much anxiety, they just don’t really own up to it.
Dan Meyer (21:20):
Ooh, yikes.
Dr. Erin Maloney (21:21):
So thoughts are, you know, there’s a bit of an apprehension for males to admit experiencing the anxiety. But I think one of the things that is extremely interesting about it—at least to me—is that we don’t tend to see gender differences in young children. So in early elementary school, even though we’ll see that kids as young as six years old will experience anxiety about math, and that that anxiety is related to how well they do in math and how much they enjoy math, it doesn’t seem to vary as a function of gender at that young age. It doesn’t seem to be related to gender until kids are at about sixth, seventh grade that we really start to see this gender difference coming online. And so that, to me, suggests that it’s probably something more social than biological at play. It probably has something more to do with these stereotypes and stuff. But another really interesting—or at least, I’m biased, but to me—another really interesting line of research that comes into play—and some of this is stuff out of my own lab—so we know that boys in general tend to do better at spatial processing than girls. And we know that spatial processing is really important for math, right? So math and space are pretty connected. And by spatial processing, I mean things like being able to picture something rotating in your mind or, you know, envisioning how these puzzle pieces might fit together. And so we know that boys tend to do better at that type of processing. And the gender difference there seems to be related to gender differences in math anxiety. So there’s some speculation, too, that it might be that as the math starts to become more reliant on spatial processing, that that’s when we see this separation between boys and girls with respect to how much anxiety they feel about math. So a lot of this is to say, I think the answer to the gender question right now is what I think what we would officially call a bit of a hot mess, <laugh> where I think there’s probably more questions than answers. But I think that there’s definitely something going on. And it really seems to be coming on later in elementary school.
Dan Meyer (23:32):
That’s a refreshingly honest admission from a social scientist, that it’s a hot mess and not perfectly clear, <laugh> so I appreciate that. It’s interesting what you said about the spatial reasoning. In our work creating curriculum at Amplify, I find we lean a lot on trying to tie abstract math towards spatial topics. Like, can you estimate a quantity before you calculate it? Can you identify a pattern and where it breaks before you prove it abstractly? And, I dunno, it’s just interesting to me. I’m just thinking out loud about how I feel like math becomes more abstract rather than more spatial. The farther you venture into secondary math…I’m wondering if I misunderstand what you’re meaning by spatial, and the progression of math from K–12.
Dr. Erin Maloney (24:20):
Yeah, so I think you can still have—you can have math be abstract, but still really relying on spatial processing. Right? And I think part of that is maybe a bit of us having different definitions of when we say “spatial.” So in cognitive science, when we talk about spatial representations or spatial reasoning, it’s really like anything you’re picturing in your mind, any time you’re really picturing these things in your mind and manipulating those images at all. So if you imagine, even like at a simple level, but it’s gonna hold when you’re going more complex as well. So doing like equivalence problems, for example, where you have to balance the equations.
Dan Meyer (24:58):
Yeah.
Dr. Erin Maloney (24:59):
Even just being able to envision things kind of moving around that equal sign and bringing one piece of the equation from this side to the other is actually an extremely spatial kind of reasoning. Right? Or when you’re expanding, that’s actually extremely extremely spatial, despite the fact that it might not feel like it initially. Obviously anything in geometry is going to be very spatial. So I think, in that sense, we would argue that the spatial processing is still playing a pretty important role. But it’s maybe a different type of spatial processing than what we’re seeing at a very early level in elementary school. That said, you can completely disagree with me too. ‘Cause I could also just be wrong, and that’s fair. My kids tell me I’m wrong all the time. So I’m used to <laugh> being told that I’m wrong.
Dan Meyer (25:47):
Well, we’re a bit more deferential on this here show, with our guests. So I would not do that. But it makes sense, what you’re saying about how these are things that you manipulate in your mind, whether they are Xs and Ys or numbers and fractions. These are all things that we manipulate. That ties into differences in this spacial reasoning category, it sounds like, which then contributes to math anxiety. And it does start to feel like there’s a lot going on here, is what it feels like.
Bethany Lockhart Johnson (26:14):
You mean hot mess?
Dan Meyer (26:16):
I meant hot mess.
Dr. Erin Maloney (26:17):
Yeah. <laugh>, I think that’s the technical term, right? I’m pretty sure that’s the technical term for it.
Dan Meyer (26:21):
I didn’t know the citation for it. So I didn’t say it. But I knew who in literature named that. But yeah.
Dr. Erin Maloney (26:28):
I’ll write something at some point.
Dan Meyer (26:30):
We’ll cite Maloney, 2022. Yeah. Yes.
Bethany Lockhart Johnson (26:34):
So I will say that one of my dreams in thinking about this season and last season, but particularly this season, since we’re really getting to talk to some researchers who get to think about this, and have really interesting conversations about it all the time…one of my dreams is that we’re bringing—’cause we do have some folks who are researchers that are listening, right? But then we also have teachers and folks who are in the classroom every day, and parents and caregivers listening. And so I think one of the beautiful things about the way that I hear you talking about it is you’re thinking about the research, but it’s so applicable. Right? And I wonder if there’s anything else you can say around it. I wanna reduce that divide, that gap, between the research that’s happening and then what’s happening with the kiddos and in the classroom and at home. And I don’t know if it’s like a magic wand thing where like <laugh> if there were changes you’d wanna see at a societal level, to try to combat math anxiety, but you see where I’m going. You know, it’s like <laugh>….
Dr. Erin Maloney (27:39):
- So I’m gonna answer maybe in two ways. So I think the first thing that I’m hearing from you is that idea of diminishing this divide, right? And so one thing I try to keep in mind, as someone who’s a researcher and working in the lab, I will often be called in to talk to teachers and give professional development sessions. And they often want the sage-on-the-stage academic, that stands up there and tells you the answers to things. And one of the first things that I’m gonna admit when I get up there is, “I am not on the front lines.” So what I do in the lab, for me to tell you that that’s gonna work in a classroom of 30 kids who may or may not have eaten dinner that day, and may or may not have snow pants, and may or not…like it’s–
Bethany Lockhart Johnson (28:23):
Mmm, yes.
Dr. Erin Maloney (28:24):
You know, I think we also need to be a little bit reasonable. So I try really hard in my own program of research to make sure that I’m always talking to teachers and to principals and to curriculum designers to make sure that the ideas that I have make sense. In fact, one of the most recent book chapters that I wrote, I wrote in collaboration with a really good friend of mine who’s a principal, an elementary school principal, and a former math consultant. And we wrote it together, to really say like, “Hey, here’s how we can help each other inform how research can inform practice and how practice can also inform research.” ‘Cause he can come to me and say, “I’m doing this. I can’t find anything in the literature to support this, but I’m sure it works!” And we can design something in the lab to test whether or not it seems like it’s gonna work.
Bethany Lockhart Johnson (29:11):
That’s huge. Yeah.
Dr. Erin Maloney (29:12):
Empirically. And so I think that open communication is massive. One thing that we’re doing in my own lab to try to keep that open communication available. So to anyone listening who’s ever tried to get access to a journal article, they’re held behind paywalls, right? So one, the way it works, my understanding of this anyway, is that the journal owns the formatted version of the paper. So what we do is we put up audio recordings of all of the research papers that we ever publish. So I’m pretty sure I own the words as the author, and the journal owns the prettified version that you can buy. So we audio-record all of our papers, so that if teachers or parents ever want to hear the actual science that’s going into some of these decisions, they have access to at least the stuff that we do in our lab. And we also put up an infographic for every paper, just highlighting kind of the main questions and main findings. And we do that because I think that the only way for the information to actually be useful is if it gets into the hands of the stakeholders that actually need that information.
Bethany Lockhart Johnson (30:21):
And is accessible. That’s huge. That’s huge!
Dr. Erin Maloney (30:24):
Yeah. Yeah. So that’s one way that we try to do it. And like I said, the other thing, we try to always be working with principals and with teachers. I joke that the way that I remedied this in my own life…so my husband’s a teacher; it’s like, I just married one! It’s fine! <laugh> I can grill him on a regular basis, and be like, “I wanna try this experiment. Do you think it’s gonna work?” And he can say, like, “It’s not going to. Here’s why.”
Dan Meyer (30:47):
That’s awesome. Marrying a participant—you know, a research participant—is unethical, of course. Would not clear IRB. But turning your partner into a participant? Like, what are you gonna do? That’s great.
Dr. Erin Maloney (30:57):
Yeah, no, that’s fair game.
Dan Meyer (30:58):
Yep.
Dr. Erin Maloney (30:59):
Yeah. So that’s—I think we we compensate each other <laugh>. So, no…so I do joke a little bit about that. He was a teacher simply ’cause he wanted to be one. Not ’cause I needed him to be one. But, I think that communication part is, is really key. That’s one thing. Then the other part of the question or the other sort of piece of the question that I was hearing is that idea of, how do we fix math anxiety. Right? Like, what’s the great, “I’m glad that there’s a whole bunch of time and effort and energy going into trying to understand this, but what, where are we at?” And I think with that, it’s really, really promising. So there’s been a lot of research coming out looking at how best to help children or even adults manage their own anxiety about math. And there’s a few really interesting strategies that seem to be quite effective. So one, and I don’t know if—um, it feels weird calling him Dr. Ramirez, just ’cause I know him well!—but I don’t know if Dr. Ramirez would’ve talked about this when he chatted with you, but he has some really interesting work on expressive writing. Did he chat about that at all?
Bethany Lockhart Johnson (32:07):
He didn’t, but I’ve read some of his work about it and I think it’s so fascinating.
Dr. Erin Maloney (32:11):
Yeah! So, OK, well, I’ll tell you about his work on it.
Bethany Lockhart Johnson (32:13):
Yes, please. Please.
Dr. Erin Maloney (32:14):
Because it’s super-useful. So when we talked about that idea of how anxiety causes these thoughts and ruminations, and they tie up the memory resources that you need, what Gerardo has found is that when you get students to write about their anxiety for about 10 minutes before they do a test, what ends up happening is they end up doing better on the test, relative to if they would not have written about their anxiety at all. And this is particularly true for students who are really high in anxiety. OK? And the idea is that all of those thoughts that they were going to have about the test or the consequences of the test, et cetera, you just kind of get ’em…it’s like a mind dump where you get ’em all onto the page at first before you even go to do the test. And now when you go to do the test, you’re not having to do two things at once. You’re no longer dealing with these thoughts ’cause you got ’em all out on the paper beforehand. And so Gerardo has some really interesting work showing that that works for math anxiety. And then it also works for just testing anxiety in general. And so that’s a strategy that I love. I also—part of what I really love about it is it’s so low-cost, right? You need a paper and a pencil and it’s great. So those are always my favorite strategies, the ones that don’t really cost us anything. So that’s one way of dealing with like the cognitive part of the anxiety. The other thing you can do is try to deal with the anxiety part of the anxiety. So for that, what we find is that the typical strategies that you’re gonna see for anxiety tend to work for math anxiety. So things like focused breathing. Right? Making sure you’re doing deep inhales and exhales. That really diaphragmatic breathing seems to be quite helpful. We know that what we call progressive desensitization is really key. That’s the idea of doing things, you know, starting with the questions that you know how to handle. And then gradually working up to the more difficult questions. So you’re sort of gradually exposing yourself to the more complex stuff. And how that can play out on an actual test at school is, you sit down, and instead of just starting with question number one, you actually read the whole test, see which questions you feel like you know the best, start with those questions, and that helps build your confidence so that you’re better able to tackle the questions that are maybe a little bit outside of where you’re currently at. So that seems to be really helpful. The other part that I will say, too, that’s extremely helpful: So we know that anxiety really ties up those memory resources. And so the more you can make the math automatic, the more immune it’s going to be to anxiety in the moment. And so I know that this part can be a little bit controversial, because we don’t wanna necessarily demotivate children, and kill the enthusiasm for math that we’re trying to cultivate…but really, you know, really committing your arithmetic facts to memory can be extremely helpful. So really learning those times tables, really learning your addition and subtraction facts. ‘Cause what happens is, then when you’re in a situation where you need that information, even if you’re anxious and you’re working with fewer cognitive resources than what you would normally have, you actually don’t need that many cognitive resources to be able to pull something from memory that you’ve memorized. So it really helps to kind of protect you against some of the negative impacts of the anxiety while you’re doing that test.
Bethany Lockhart Johnson (35:37):
And you’re not using all your cognitive resources to figure out seven times eight, because you can really focus on what you’re trying to do with that. Oh, that’s fascinating. Yeah. Yeah.
Dr. Erin Maloney (35:47):
Yes. No, a hundred percent right. And so I know that’s one that, like I said, I know it can be somewhat controversial because it’s…you know, we’ve talked about—or we haven’t talked about in this conversation, but we often talk about—the idea of drilling and killing. Right? So you drill the facts, you kill the, the enthusiasm. But I think that there are ways that we can drill arithmetic facts, or help make them automatic, but still fun, right? It doesn’t have to always be in a high-pressure kind of way.
Bethany Lockhart Johnson (36:16):
Totally. And we’ve talked about fluency, and I’m sure we’ll talk about it more in the Lounge. And that is interesting, that link between anxiety when the fluency isn’t there, that—or, of course we hear about anxiety with timed tests, but the idea of that IS something you can do to reduce it, because you have those facts just at your ready. Right?
Dr. Erin Maloney (36:37):
Yeah. So I actually, again, I’m gonna be a little bit controversial. So I don’t hate timed tests in the way that a lot of people do. But I love time to practice. So I think once we’ve got to a point where children have a fairly decent understanding of skills, of a skill, once they’ve got a fairly decent grasp on it, then I love the idea of the timed practice. So it can be still in a low-pressure situation, where in many ways it doesn’t matter if you get the answer to the question correct. But we’re practicing doing it in a situation in which you might be feeling a little bit of pressure, but it’s not real pressure, if that makes sense. And I think that can be really, really useful for students. And again, it can be done in a fun way, right? It doesn’t have to be these super-intense ways. It can be fun. But I think that in life there are situations in which the time that it takes you to complete a problem matter. And I think that we have to make sure that we don’t get too far away from that.
Dan Meyer (37:40):
Yeah. It feels like we should do an entire other episode thinking about ways to develop that fluency and automaticity that don’t contribute to anxiety, or create further disparities between people who are high math anxiety and low math anxiety. Not a small question, I’m sure. And I appreciate you alluding to all of that. You know, this whole thing, as you said, is quite the hot mess. And I feel like you, Dr. Maloney, have helped us make this a little less messy, in our heads, and hopefully the listeners’ heads. I really appreciate that. I just love…you’ve mentioned lots of resources that you have. You’ve alluded to them: audiobook-style readings of your research, which I need ’cause I just finished, you know, Harry Potter, the seventh book, so I need a new thing to listen to like that. Also infographics. Can you tell our listeners where they can find this work of yours, and if there are any other kinds of resources that you wanna plug for our listeners here?
Dr. Erin Maloney (38:32):
Yeah, for sure. So all of our resources can be found on my lab website. So the address for that is www.ErinMaloney.ca. So there we have, like you said, the infographics and the audio articles and all that stuff. And then we also have a link to a new kids’ book out, actually, that a colleague of mine and I have published recently, that really walks through some of these strategies on combating math anxiety. The book is written as a children’s book, so it’s Peyton & Charlie Challenge Math. But it secretly is a book that would also work for adults. So if you are a parent that’s a little bit anxious about math, or a teacher that maybe is a little bit anxious, and you wanna see how some of these strategies can play out, in that book—we linked to it on the website, but it is available for purchase on Amazon. And the one thing I will say about the book, ’cause this is something that we were pretty proud of, so Sheri-Lynn Skwarchuk, who is a school psychologist, and I wrote the book. And it’s available for purchase at our cost price, so we don’t actually make any money on the book. It was literally just a way of getting some of the science out to people who might be able to benefit from it.
Bethany Lockhart Johnson (39:45):
Reducing that divide!
Dr. Erin Maloney (39:46):
Yeah, well that’s what we’re trying to do! Right? So I think in the U.S., I think it’s like $6 on Amazon. And then in terms of other resources, we’re in the process right now of creating some informational videos and and stuff like that that hopefully will be useful for parents and for teachers, just in terms of understanding a little bit more about the anxiety and understanding how to deal with the anxiety in the classroom more, at home or wherever it might be coming up.
Dan Meyer (40:15):
Well, thanks so much. I really appreciate—we appreciate!—you coming on, and hearing about how you’re trying to bridge so many different barriers from research to practice, and school to home. It’s just really inspiring. And we’d love to have you back on sometime. So thank you so much for joining us.
Bethany Lockhart Johnson (40:29):
I feel like we’ve just hung out! Don’t you, Dan?
Dan Meyer (40:31):
Are we rolling here? Oh my gosh, we’re rolling. I just thought we’re just hanging. Yeah,
Bethany Lockhart Johnson (40:34):
I thought we were just hanging!
Dr. Erin Maloney (40:36):
I know, I do, I really appreciate that it has a very kind of chill vibe to it.
Dan Meyer (40:41):
Chill vibe. Like a lounge.
Bethany Lockhart Johnson (40:42):
It’s the lounge!
Dan Meyer (40:43):
Thank you. You get us; you get us. <laugh>
Bethany Lockhart Johnson (40:45):
Dan Meyer. I was shopping for children’s books, and there was this book, and it was talking about being at home with Mom. And it’s going through all the things that the child did that day with Mom. It’s like, “We played outside, we ran through the sprinklers, we even did some homework.” And it shows them sitting at the table with the homework, that’s clearly math homework, in front of them. And the mom is like, “Harrumph!” Like a very perplexed, anxious face. And there’s all these question marks above her. And it’s just like,
Dan Meyer (41:24):
“There should not be numbers on that paper!”
Bethany Lockhart Johnson (41:25):
Exactly. And the child is like, “Ohhhh,” you know. And I mean, I have to give credit to the illustrator, because they really did capture the clear message of this interaction, which was sitting down to do math homework or think about math together is a source of angst. Right? According to this author and according to too many people. And so I think what’s really important is that we recognize those images when we see them out there and speak back to them, and say, “Hey, wait a second.” Yeah, it can feel like that, and it doesn’t have to. And what’s going on that that’s just the assumed way that it’s gonna feel, to sit down and math together. You know?
Dan Meyer (42:11):
Yeah. It feels like we all have a lot of work to do on the whole math-anxiety front. Dr. Maloney helped us see how parents play a part, educators play a part, society and how they create people plays its own part in how we all define math as a thing where we evaluate student thought or where students play it with their thoughts, has its own huge part as well. So yeah, it was a really fantastic conversation with Dr. Maloney. I hope you folks will check out the show notes, where you will find links to Dr. Maloney’s website. A lot of her work, which as you heard, is very geared towards practitioners and parents and even directly at kids, especially the new children’s book she co-authored, Peyton & Charlie Challenge Math.
Bethany Lockhart Johnson (42:55):
Next time we’re gonna dive even more into the nitty gritty of combating math anxiety. To do that, we’re actually gonna be joined—I am so excited about this—by Dr. Rosemarie Truglio from Sesame Workshop.
Rosemarie Truglio (43:09):
Our core audience are two- to four-year-olds, and they love math. And what’s not to love? Children don’t come with this math anxiety. Math anxiety is learned.
Dan Meyer (43:23):
So excited.
Dr. Erin Maloney (43:24):
Sesame Street was a huge part of my childhood and my toddler doesn’t know it yet, but Sesame Street is coming. It’s coming. Like, we’re we’re gonna introduce Sesame Street to him. We just haven’t yet.
Dan Meyer (43:37):
Sesame Street straight raised me.
Bethany Lockhart Johnson (43:38):
Right?
Dan Meyer (43:39):
Yeah. Don’t tell my parents. But that’s, yeah, that’s true. I’m excited, too. It’s gonna be a blast.
Bethany Lockhart Johnson (43:45):
I’m really excited. I think that the more we dive into this topic—which, again, we’re gonna look at math anxiety from a lot of different angles—and I’m excited to talk to Dr. Truglio about how we can take this research and these conversations that are happening about math and how it can actually impact what’s happening in homes. ‘Cause we wanna help create positive relationships with mathematics, with kids in math. I’m so excited. And I hope you folks keep listening. We love having you here in the Lounge. And if you haven’t already, please subscribe to Math Teacher Lounge, wherever you get podcasts. And if you like what you’re hearing, please leave us a rating and a review. It helps more listeners to find the show, and let other folks know about this show. Recommendations are great. Thanks so much for listening.
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Meet the guest
Erin Maloney is an Associate Professor and Canada Research Chair at the University of Ottawa. Her research sits at the intersection of Cognitive Psychology, Developmental Psychology, and Education and focuses on cognitive and emotional factors that relate to academic achievement. She is a world-renowned expert on the study of math anxiety, conducting research in the lab, in homes, and in classrooms with children, parents, and their teachers. She is passionate about both knowledge mobilization and equity, diversity, and inclusion within education and science.
About Math Teacher Lounge
Math Teacher Lounge is a biweekly podcast created specifically for K–12 math educators. In each episode co-hosts Bethany Lockhart Johnson (@lockhartedu) and Dan Meyer (@ddmeyer) chat with guests, taking a deep dive into the math and educational topics you care about.
Join the Math Teacher Lounge Facebook group to continue the conversation, view exclusive content, interact with fellow educators, participate in giveaways, and more!
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One of the research-based frameworks used in the Science of Reading is the Simple View of Reading.
According to the Simple View, two cognitive capacities are required for proficient reading: (1) word recognition and (2) language comprehension.
“Reading comprehension is the product, not the sum, of those two components. If one of them is zero, then overall reading ability is going to be zero,” says Jane Oakhill, Ph.D., professor of experimental psychology at the University of Sussex.
Those two skills make up the two meta-strands of the Rope. But, as Oakhill explains further on her episode of Science of Reading: The Podcast, each strand contains its own subset of distinct skills and processes.
What are the strands of the Reading Rope?
Let’s take a look:
- Word recognition encompasses the ability to accurately and swiftly decode printed words. Phonological awareness, phonics, and sight word recognition contribute to this strand.
- Phonological awareness is the ability to recognize and manipulate the individual sounds (phonemes) within spoken words. It includes skills such as identifying rhymes, segmenting words into syllables, and manipulating sounds within words. Phonological awareness provides the foundation for phonics instruction.
- Phonics describes the systematic relationship between letters and the sounds they represent. It includes understanding letter-sound correspondences, decoding unfamiliar words by applying sound-symbol relationships, and blending sounds to form words. Phonics instruction gives students the tools to decode printed words.
- Sight word recognition is the ability to recognize and read words automatically, without decoding. Building a repertoire of sight words boosts fluency.
- Language comprehension is the understanding of spoken and written language, including vocabulary, grammar, syntax, and the ability to make inferences and draw conclusions. Language comprehension allows readers to extract meaning from text.
- Vocabulary refers to the words one knows and understands, both orally and in writing. A robust vocabulary enhances comprehension and communication.
- Grammar and syntax are the rules and structures that govern language. Understanding and applying grammatical rules helps students comprehend and construct sentences, enhancing their ability to make meaning from text.
- Inference and conclusion skills describe the abilities of drawing conclusions, making predictions, and deriving implicit meaning. These skills require readers to combine their background knowledge with information in the text to make guesses and reach conclusions.
How do the strands combine to form a process?
These strands are interconnected and mutually supportive. Strong word recognition skills enable efficient decoding, which frees up cognitive resources for language comprehension. Similarly, robust language comprehension skills facilitate deeper word understanding and contextualized reading.
That’s how the Rope represents not just the elements of learning to read, but also the process toward fluency. As students progress, their word recognition becomes increasingly automatic, and their language comprehension becomes increasingly strategic.
- In the word recognition strand, readers focus on decoding individual words, relying on phonological awareness and phonics. With practice and instruction, word recognition becomes more efficient and effortless. This automaticity frees up cognitive resources for comprehension and higher-level thinking.
- In the language comprehension strand, readers learn to engage actively with the text, ask questions, make connections and predictions, and monitor understanding. Strategic readers use comprehension strategies—summarizing, visualizing, self-questioning, and more—to deepen their understanding of what’s on the page.
Those two processes are intertwined and interdependent. The Rope shows that, as readers progress, they get better at combining automatic word recognition with strategic reading skills.
They can effortlessly recognize words, allowing them to focus on comprehending the text and performing higher-level thinking. By strategically applying language comprehension skills, readers construct meaning, make connections, and analyze the text.
This combination of automatic and strategic skills supports reading and facilitates engagement with more complex and challenging texts.
How does the Rope relate to the five foundational skills of reading?
The Rope is made of a lot more than the five foundational skills of reading (phonics, phonemic awareness, vocabulary, fluency, and comprehension). How does it all add up?
While the Reading Rope does not explicitly mention these five skills as a distinct set, the strands do align with them. Here’s how:
- Phonological awareness (and phonemic awareness) is represented in the Rope’s word recognition strand.
- Phonics is also a critical aspect of word recognition.
- Fluency—often considered a combination of accuracy, rate, and prosody—is not represented as its own strand, but it’s closely related to the word recognition strand. As students develop automaticity in word recognition, their reading fluency improves.
- Vocabulary aligns with the language comprehension strand. The development of a robust vocabulary enhances reading comprehension by enabling students to understand and infer the meaning of words encountered in the text.
- Comprehension is built into the language comprehension strand. It includes skills such as understanding sentence structure, making inferences, drawing conclusions, and connecting prior knowledge. These skills help the reader get meaning from the text and connect to higher-level thinking.
The Reading Rope is a game-changing tool, clarifying a complex process and helping teachers target instruction. When the strands come together, they weave the strongest possible foundation for student reading success.
Amplify Desmos Math California
Welcome, K–8 Reviewers!
We’re honored to introduce you to Amplify Desmos Math California. We’re confident you’ll find this comprehensive program to be a powerful tool for bringing the vision of the California Math Framework to life in classrooms across the state.
Please start with the video on the right to learn how to navigate the program and access key features referenced within our submission. Below you’ll find additional resources to support your review.
Your Review Samples
As a curriculum that incorporates both print and digital resources, it’s important that you explore both our physical materials (delivered to you in grade-specific tubs) and our digital materials (accessible through our platform). We invite you to explore both types of resources using the instructions and tips below.
Print Samples
Your print samples should have arrived in grade-specific tubs with a copy of two Reviewer binders. The K-5 Reviewer binder is contained within the Grade K shipping box and the Grade 6-8 Reviewer binder can be located in the Grade 6 shipping box. As you begin the process of organizing your materials, please refer to the inventory checklist found inside each tub as well as within your Reviewer Binder.
Digital Samples
In order to access your digital samples, you’ll need to log into our platform using your unique login credentials found on a Digital Access Flyer inside of your Reviewer Binder. Once you have located the flyer:
- Click the orange button below to access the platform.
- Click “Log in with Amplify.”
- Enter the username and password provided on your Digital Access Flyer.
Navigation Tips
Below you will find helpful tips for navigating Amplify Desmos Math California. We recommend reading these pages alongside the program’s print materials and digital experience to gain a deeper understanding of the program.
Click the links below to read about navigating program features including:
- Navigating the print program (Grades K–1)
- Navigating the print program (Grades 2–5)
- Navigating the print program (Grades 6–8)
- Navigating the digital program
Built for California
The Amplify Desmos Math California program is designed around the vision articulated in the California Mathematics Framework to enable all California students to become powerful users of mathematics. Our program incorporates the latest research in student learning, meaning that we:
- Focus on the Big Ideas: Amplify Desmos Math California’s courses, units, and lessons are centered around the Big Ideas. Big Ideas, like standards, are not considered in isolation. In addition to each unit and lesson’s focal Big Ideas, Amplify Desmos Math California also provides connections among the Big Ideas across units and lessons.
- Center on open and engaging tasks: Amplify Desmos Math California is grounded in engaging tasks meant to address students’ often-asked question: “Why am I learning this?” Students are invited into learning with low-floor, high-ceiling tasks that provide an entry point for all. Open tasks in Amplify Desmos Math California provide the space for students to try on multiple strategies and represent their thinking in different ways, and allow student explanation and discussion to serve as the center of the classroom. All lessons offer both print and digital representations of lessons.
- Provide enhanced digital experiences: Amplify Desmos Math California includes digitally-enhanced lesson activities, incorporating interactive digital tools alongside print materials. These purposefully-placed resources allow students to visualize mathematical concepts, receive actionable feedback while practicing, encounter personalized learning support from an onscreen tutor, and engage in discussions about their thinking and approaches.
- Treat core instruction and differentiation as integral partners: The Amplify Desmos Math California curriculum provides teachers with lessons, strategies, and resources to eliminate barriers and increase access to grade-level content without reducing the mathematical demand of tasks. Every activity has multiple entry points to ensure that all students are supported and challenged. Intervention and personalized learning activities are directly connected to lesson content and offer students the individualized support as they dive into the mathematics.
Category 1: Mathematics Content/Alignment with the Standards
Standards Maps
The links below provide the Standards Maps for Amplify Desmos Math California for each grade level.
Evaluation Criteria Map
Linked here is the Evaluation Criteria Map for grades K–8. Please note that you will need to be logged into the digital platform to access the links in the Evaluation Criteria Map.
Standards for Mathematical Practice
The links below provide the alignment of Amplify Desmos Math California to the Standards for Mathematical Practice at each grade level.
Drivers of Investigation and Content Connections
Amplify Desmos Math California incorporates the Drivers of Investigation (DIs) and Content Connection (CCs) throughout the program. Throughout the year, students engage with open and authentic tasks of varying durations — from lesson activities to unit-level Explore lessons and longer course-level Investigations. Every lesson and investigation opportunity is grounded around the why, how, and what of the learning experience, and helps teachers bring mathematical concepts to life.
California English Language Development Standards
The links below provide the alignment of Amplify Desmos Math California to the California English Language Development Standards at each grade level.
California Environmental Principles and Concepts
Select lessons, performance tasks, and investigations across grade levels in Amplify Desmos Math California are aligned to one or more of the California Environmental Principles and Concepts. Click the links below to view how the California Environmental Principles and Concepts are represented in each grade level.
Category 2: Program Organization
Amplify Desmos Math California thoughtfully combines conceptual understanding, procedural fluency, and application. Each lesson is designed to tell a story by posing problems that invite a variety of approaches before guiding students to synthesize their understanding of the learning goals.
Big Ideas
Amplify Desmos Math California’s courses, units, and lessons are centered around the Big Ideas. In addition to each unit and lesson’s focal Big Ideas, Amplify Desmos Math California also provides connections among the Big Ideas across units and lessons. Please refer to Keeping the Big Ideas at the Center (linked below) for specific lesson designs and alignment with the Big Ideas for each grade level.
Program Structure
Amplify Desmos Math California combines the best of problem-based lessons, intervention, personalized practice, and assessments into a coherent and engaging experience for both students and teachers.
Lessons and units in Amplify Desmos Math California are designed around a Proficiency Progression, a model that steps out problem-based learning by systematically building students’ curiosity into lasting grade-level understanding.
In the Proficiency Progression, lessons begin by activating students’ natural curiosity and offering opportunities to generate new ideas through collaboration. Teachers are then able to refine ideas through intentional facilitation and guide students to grade-level understanding, while students retain the ability to use different strategies and methods to show their comprehension of the content. Students are provided ample opportunities to develop lasting understanding.
Scope and Sequence
Below you can view the scope and sequence for each grade level.
Lesson Design and Structure
Amplify Desmos Math California is designed with a structured approach to problem-based learning that systematically builds on students’ curiosity and allows students to grapple with the Big Ideas of the California Framework. Every lesson activity is organized into a Launch, Monitor, Connect format.
- Launch: The launch is a short, whole-class conversation that creates a need or excitement, provides clarity, or helps students connect their prior knowledge or personal experience, which ensures that everyone has access to the upcoming work.
- Monitor: As students work individually, in pairs, or in groups, teachers explore student thinking, ask questions, and provide support to help move the conversations closer to the intended math learning goal.
- Connect: Teachers connect students’ ideas to the key learning goals of the lesson, facilitating class discussions that help synthesize and solidify the Big Ideas.
Each lesson within Amplify Desmos Math California follows the same structure.
- Warm-Up: Every Amplify Desmos Math California lesson begins with a whole class Warm-Up. Warm-Ups are an invitational Instructional Routine intended to provide a social moment at the start of the lesson in which every student has an opportunity to contribute. Warm-Ups may build fluency or highlight a strategy that may be helpful in the current lesson or act as an invitation into the math of the lesson.
- Lesson Activities: Each lesson includes one or two activities. These activities are the heart of each lesson. Students notice, wonder, explore, calculate, predict, measure, explain their thinking, use math to settle disputes, create challenges for their classmates, and more. Guidance is provided to help teachers launch, monitor, and connect student thinking over the course of the activity.
- Synthesis and Show What You Know: The Synthesis is an opportunity for the teacher and students to pull all the learning of the lesson together into a lesson takeaway. Students engage in a facilitated discussion to consolidate and refine their ideas about the learning goals, and the teacher synthesizes students’ learning. Show What You Know is a daily assessment opportunity for students to show what they know about the learning goals and what they are still learning.
- Centers (K–5): Centers are hands-on activities for students in grades K–5 to play collaboratively to strengthen their understanding of key skills and concepts. In grades K–1, students have Daily Center Time built into every lesson.
- Practice and Differentiation: Daily practice problems for the day’s lesson are included both online and in the print Student Edition, including fluency, test practice, and spiral review.
Kindergarten–Grade 1
Grades 2–5
Grades 6–8
Routines
Amplify Desmos Math California features a variety of lesson routines. Instructional routines and Math Language Routines (MLRs) are used within lessons to highlight student-developed language and ideas, cultivate conversation, support mathematical sense-making, and promote meta-cognition. Both are called out at point-of-use within the Teacher Edition and Teacher Presentation Screens. Below are the types of routines used throughout the Amplify Desmos Math California curriculum:
Math Language Routines
- MLR1: Stronger and Clearer Each Time
- MLR2: Collect and Display
- MLR3: Critique, Correct, Clarify
- MLR5: Co-Craft Questions
- MLR6: Three Reads
- MLR7: Compare and Connect
- MLR 8: Discussion Supports
Instructional Routines
- Decide and Defend
- Notice and Wonder
- Number Talk
- Tell a Story
- Think-Pair-Share
- Which One Doesn’t Belong?
Category 3: Assessments
A variety of performance data in Amplify Desmos Math California provides evidence of student learning, while helping students bolster their skills and understanding.
Unit-Level Assessment
Amplify Desmos Math California has embedded unit assessments that offer key insights into students’ conceptual understanding of math. These assessments provide regular, actionable information about how students are thinking about and processing math, with both auto-scoring and in-depth rubrics that help teachers anticipate and respond to students’ learning needs.
- Pre-Unit Check: Each unit in grades 2–8 begins with a formative assessment designed to identify the student skills that will be particularly relevant to the upcoming unit. This check is agnostic to the standards covered in the following unit and serves not as a deficit-based acknowledgment of what students do not know, but rather as an affirmation of the knowledge and skills with which students come in.
- End-of-Unit Assessment: Students engage with rigorous grade-level mathematics through a variety of formats and tasks in the summative End-of-Unit Assessment. A combination of auto-scored (when completed digitally) and rubric-scored items provides deep insights into student thinking. All Amplify Desmos Math California End-of-Unit Assessments include two forms.
- Sub-Unit Quizzes: Sub-Unit Quizzes are formative assessments embedded regularly in Grades Kindergarten through Algebra 1. In these checks, students are assessed on a subset of conceptual understandings from the unit, with rubrics that help illuminate students’ current understanding and provide guidance for responding to student thinking.
- Sub-Unit Checklists: These checklists enable teachers to observe key skills and concepts that cannot be assessed on a pencil-and-paper assessment in Kindergarten–Grade 1. The checklists outline the supports students need to achieve mathematical growth and success.
- Performance Tasks: At the end of each unit in grades 3–8, there is a summative assessment performance task provided to evaluate students’ proficiency with the concepts and skills addressed in the unit.
Lesson-Level Assessments
Amplify Desmos Math California lessons include daily moments of assessment to provide valuable evidence of learning for both the teacher and student. Beyond formative, summative, and benchmark assessments, students also have opportunities for self-reflection with Watch Your Knowledge Grow. Students take ownership of their learning by reflecting and tracking their progress before and after each unit.
- Show What You Know: Each lesson has a daily formative assessment focused on one of the key concepts in the lesson. Show What You Know moments are carefully designed to minimize completion time for students while maximizing daily teacher insights to attend to student needs during the following class.
- Responsive Feedback™: Teachers have the ability to see and provide in-the-moment feedback as students progress through a digital lesson. Responsive Feedback motivates students and engages them in the learning process.
Diagnostic Assessment
Every grade level features an asset-based diagnostic assessment designed to be administered at the beginning of the year. Delivered digitally and to the whole class, our diagnostic assessment is uniquely designed to reveal underlying math thinking and identify what students know about grade-level math. With data beyond just right and wrong, teachers have the type of deeper level of insights need to take the right next step.
CAASPP-Aligned Assessment Preparation
Amplify Desmos Math is designed to support students’ mathematical development through problem-based learning, differentiation, and embedded assessments. The program’s emphasis on conceptual understanding, procedural fluency, and application aligns with the mathematical practices and content standards assessed by the CAASPP.
Amplify Desmos Math California includes a CAASPP-aligned Item Bank. This standards-aligned bank of questions allows teachers to filter and search by grade and standard to find items. Once assigned on the digital platform, students will experience CAASPP-like practice with the online digital tools.
Data and Reporting
Amplify Desmos Math California provides teachers and administrators with unified reporting and insights so that educators have visibility into what students know about grade-level math—and can plan instruction accordingly for the whole class, small groups, and individual students. Reporting functionality integrates unit assessments, lesson assessments, diagnostic data, and progress monitoring for a comprehensive look at student learning. Program reports show proficiency and growth by domain, cluster, standard, and priority concept using performance data from unit assessments, then highlight areas of potential student need to allow teachers to modify their instruction and target differentiated support.
Administrator reporting provides a complete picture of student, class, and district performance, allowing administrators to implement instructional and intervention plans.
Category 4: Access and Equity
The Amplify Desmos Math California curriculum provides teachers with lessons, strategies, and resources to eliminate barriers and increase access to grade-level content without reducing the mathematical demand of tasks. Our lessons are developed using the Universal Design for Learning (UDL) framework to proactively ensure that all learners can access and participate in meaningful, challenging learning opportunities.
Every activity has multiple entry points to ensure that all students are supported and challenged. Intervention and personalized learning activities are directly connected to the day’s content and offer students the individualized supports they need to be successful.
Each lesson and unit contains guidance for teachers on how to identify students who may need support, students who need to keep strengthening their understanding, and students who may be ready to stretch their learning. In addition, teachers are provided with recommendations for resources to use with each group of students.
Universal Design for Learning
Each lesson in the program incorporates opportunities for engagement, representation, action, and expression based on the guidelines of Universal Design for Learning (UDL).
- Multiple Means of Engagement: Students engage in both print and digital learning, and are regularly participating in discussions and hands-on activities. Students are invited to build their own challenge for other students to solve, which provides opportunities for choice and
autonomy, as well as joy and play. - Multiple Means of Representation: Students are encouraged to demonstrate their learning using mathematical representations, both print and digital, and regularly engage with their peers in analyzing multiple possible solutions. Classes engage in open-ended discussions about what individual students notice and wonder about mathematical concepts.
- Multiple Means of Action and Expression: Learners differ in how they navigate learning environments and express what they know. Students can communicate their ideas in multiple ways, including in print, sketching, uploading photos, or recording an audio response.
Accessibility
Lesson facilitation supports
Every lesson includes at least one specific suggestion the teacher can use to increase access to the lesson without reducing the mathematical demand of the tasks. These suggestions address the following areas:
- Visual-spatial processing
- Conceptual processing
- Executive functioning
- Memory and attention
- Fine motor skills
Accessibility tools
Students have the ability to control accessibility tools so that each learning experience is customized to their individual needs. In many instances, these tools can be turned on or off at any point of instruction.
- Text to speech: Reads text instructions to students in multiple languages
- Enlarged font: Increases the size of all text on screen
- Braille mode: Includes narration of digital interactions
- Language selection: Toggles between languages
Differentiation: In-Lesson Teacher Moves
Within every lesson activity, teachers can use the suggestions in the Differentiation Teacher Moves table to provide in-the-moment instructional support while students are engaged in the work of the lesson. This table can help teachers anticipate the ways students may approach the activity, and provides prompts that they can use during the lesson to Support, Strengthen, and Stretch individual students in their thinking. Teachers are provided with clear student actions and understanding to look for, each matched with immediately usable suggestions for how to respond to the student thinking illustrated in each row of the table. In addition to using these suggestions in the moment as teachers monitor student work, teachers can review the Differentiation table in advance to help them anticipate how students are likely to approach the activity.
Differentiation: Beyond the Lesson
Teachers are provided with recommendations for resources to use with each group of students needing support, strengthening, and stretching after each lesson. Support, Strengthen, and Stretch resources include:
- Mini-Lessons: 15-minute, small-group direct instruction lessons targeted to a specific concept or skill
- Item Banks: Space for teachers to create practice and assessments by using filters and searching for standards, summative-style items, and more
- Fluency Practice: Adaptive, personalized practice built out for basic operations and more
- Centers (K–5): Lesson-embedded routines and practice for students that are vertically aligned across grade levels
- Extensions: Lesson-embedded Teacher Moves including possible stretch questions and activities for students
- Lesson Practice: Additional practice problems support every lesson
- Math Adventures: Strategy-based math games where students engage with math concepts and practice skills in a fun digital environment
- Lesson Summary Support: Support for students and caregivers that provides efficient explanation of the learning goal with clear examples
Math Identity and Community
The Math Identity and Community feature supports teachers in helping students build confidence in their own mathematical thinking, develop skills to work with and learn from others when doing math, and learn how math is an interwoven part of their broader community. The embedded prompts throughout the lessons are designed to highlight what it means to be good at math, the value of sharing ideas, and the power of flexible and creating thinking. Here are some examples of the Math Identity and Community supports embedded in each lesson:
- I can be all of me in math class. You will work with partners every day in math class. What do you want your partners to know about you?
- We are a math community. What does good listening look like and sound like in a math community?
- I am a doer of math. What math strengths did you use today?
Unit Stories
Every unit in grades K–5 contains a Unit Story. These Unit Stories are brief fiction stories read aloud by the teacher at the beginning of each unit that connect to the math of the unit and introduce characters that students will get to know as they engage in the unit. Teachers read the story aloud from their Teacher Edition while projecting illustrations for students from the story, found in the Teacher Presentation Screens for the story. Across the unit, the Unit Story context and characters are used at appropriate points to inspire and engage students in the math as well as in reflections about their math identity and community.
Math Language Development
Every lesson in Amplify Desmos Math California includes opportunities for all students to develop mathematical language as they experience the content. Amplify Desmos Math California purposefully progresses language development from lesson to lesson and across units by supporting students in making their arguments and explanations stronger, clearer, and more precise. This systematic approach to the development of math language can be broken down into the following four categories of support:
- Vocabulary: Units and lessons start by surfacing students’ language for new concepts, then building connections between their language and the new vocabulary for that unit. This honors the language assets that students bring into their learning.
- Language goals: Language goals attend to the mathematics students are learning, and are written through the lens of one or more of four language modalities: reading, writing, speaking, and listening.
- Math Language Routines: Math Language Routines are used within lessons to highlight student-developed language and ideas, cultivate conversation, support mathematical sense-making, and promote meta-cognition.
- Multilingual/English learner supports: Supports for multilingual/English learners (ML/ELs) are called out at intentional points within each lesson. These specific, targeted suggestions support ML/ELs with modifications that increase access to a task, or through development of contextual or mathematical language (both of which can be supportive of all learners).
Multilingual and English Learner Supports
Partnership with English Learner Success Forum
Amplify partnered with the English Learner Success Forum (ELSF), a national nonprofit organization that advocates for high-quality instructional materials that are inclusive of multilingual learners. ELSF reviewed Amplify Desmos Math California, and provided directional guidance and feedback to ensure that the program reflects their research-based instructional strategies for multilingual/English learners.
Math Language Development Resources
Our Math Language Development Resources book contains lesson-specific strategies and activities for all levels of English Learners (i.e., Emerging, Expanding, Bridging). With support for every lesson, teachers are empowered to help all students, regardless of their language skills, to participate fully, grasp the material, and excel in their mathematical journey.
Multilingual Glossary
Amplify Desmos Math California includes a digital glossary for languages other than Spanish. Translations will be provided for up to nine languages.
Spanish Version
Amplify Desmos Math California will include Spanish student-facing materials beginning in the 2026–27 school year.
Category 5: Instructional Planning and Support
Amplify Desmos Math California includes a variety of embedded instructional supports to empower teachers to lead effectively and gain actionable insights into student growth and progress. Teachers are equipped with a comprehensive set of resources designed to fulfill the requirements of Category 5.
Grade-level concepts
Within the Teacher Edition front matter:
- Scope and sequence
- Big Ideas, Drivers of Investigation, and Content Connections
- Grade level standards
- Standards for Mathematical Practice
- English Language Development Standards
- Environmental Principals and Concepts
Within each Unit and Sub-Unit Overview:
- Big Ideas, Drivers of Investigation, and Content Connections
- Math that Matters Most
- Grade level standards
- Standards for Mathematical Practice
- English Language Development Standards
- Environmental Principals and Concepts
Within each Lesson:
- Big Ideas, Drivers of Investigation, and Content Connections
- Grade level standards
- Standards for Mathematical Practice
- English Language Development Standards
- Environmental Principals and Concepts
How to implement the program
At the course level (within the Teacher Edition front matter):
- Navigating the Program (both print and digital)
- Facilitating Lesson Activities with Launch, Monitor and Connect
- Overview of the Digital Facilitation Tools
At the lesson level:
- Suggestions for timing
- What materials to prep
- How to organize and group students
- Key lesson takeaways with the Synthesis
- Recommendations for Differentiation
- Strategies for intervention and extensions (in the Intervention, Extensions, and Investigation Resources book)
At the activity level:
- Differentiation recommendations
- Accessibility tips
- ML / EL tips
- Teacher look-fors
- Recommended Teacher Moves
- Prompts for guiding student thinking
- Sample student responses
Development of Math Language
A variety of language development supports are provided within the Student and Teacher Editions and Math Language Development Resources book.
At the lesson level:
- Diagrams and visuals
- Sentence frames and word banks
- Graphic organizers, including Frayer models
- Vocabulary routines
- Embedded language supports aligned to the CA ELDs
- Lesson-specific strategies for Emerging, Expanding, and Bridging
At the unit level:
- Words With Multiple Meanings
- Contextual vocabulary
At the course level:
- English/Spanish cognates
- Multilingual Glossary
Other Curriculum Guidance
- Additional Practice Resources book
- Assessment Resources book
- Assess and Respond guidance paired with each assessment opportunity
- Show-What-You-Know activities
- Answer keys and rubrics
- Performance tasks
Reading comprehension strategies grounded in science
When we teach reading using what science (specifically the Science of Reading) tells us, we guide the brain to start recognizing and understanding those letters, syllables, and words. And the most effective reading comprehension strategies depend not only on explicit instruction, but on building background knowledge.
Comprehension instruction: Breaking it down
According to the Simple View of Reading, two cognitive capacities are required for proficient reading: (1) decoding, and (2) language comprehension.
“Reading comprehension is the product, not the sum, of those two components,” says Dr. Jane Oakhill, professor of experimental psychology at the University of Sussex. “If one of them is zero, then overall reading ability is going to be zero.”
As Oakhill explains further on Science of Reading: The Podcast, each component contains its own set of distinct skills and processes. It’s crucial to help students develop all of these capacities.
Building mental models for new information
Some readers are great at decoding but struggle with language comprehension. Why might that be—and how can you support them?
Here’s some context: After you read this paragraph, you aren’t likely to recall the precise wording—but you will probably remember the idea. Researchers use the term mental model to describe the cognitive strategies for the structure you create in your mind to perform this feat of comprehension.
Historically, educators have thought about the process of comprehension — everything that happens after each word is recognized — as a black box. But now we know that there are two levels of comprehension at work: comprehension processes and comprehension products.
Comprehension processes are the steps you take to build a mental model of a text during reading. Comprehension products refer to the work you are able to do with that model after reading.
Think of the process of building a mental model as a sort of micro-comprehension. Weaker comprehenders build weaker models, so they may struggle when asked to create a narrative text summary, identify a theme, put together predictions, or describe key details of a character’s evolving beliefs.
By actively engaging with text, connecting prior knowledge, utilizing graphic organizers, receiving explicit instruction, and exploring new information, students can learn to build robust mental models that enhance their comprehension of the text. These mental models serve as frameworks for understanding, organizing, and synthesizing information, which then leads to improved comprehension, retention, and critical thinking.
Researchers have identified as many as 17 comprehension processes that affect students’ ability to build and use their mental models. The following are a few of the comprehension processes that weak comprehenders most commonly struggle with, and that with practice, can be targeted for skill development and improved overall comprehension.
- Anaphora (using pronouns to refer to an earlier word or phrase): Some readers struggle to process pronoun relationships (Megherbi & Ehrlich, 2005), identify antecedents, and answer questions that require resolution of anaphora (Yuill & Oakhill, 1988).
- Gap-filling inference: When reading the sentence “Carla forgot her umbrella and got soaking wet,” more skilled readers will conclude that it rained. A lack of awareness of when and how to activate background knowledge to fill in gaps may hinder a student’s ability to make inferences and comprehend the text as a whole (Cain & Oakhill, 1999).
- Marker words: Writers use connective words (e.g., so, though, and yet), structure cues (e.g., meanwhile), and predictive cues (e.g., “There are three reasons why…”) to signal ways that text fits together. Students with limited knowledge of the meaning and function of these words may struggle with the meaning of the text (Oakhill, et al., 2015).
- Comprehension monitoring: When proficient readers encounter difficulty, they tend to stop, reread, and try to figure it out. Less proficient readers may just keep going or fail to recognize that what they’re reading doesn’t fit their mental model.
Two strategies that you can employ in your classroom to guide students in comprehension strategy instruction:
- Graphic organizers: Use graphic organizers such as concept maps, story maps, or Venn diagrams to help students learn to visually organize information and relationships within the text. Visualization enhances comprehension (Graesser, et al., 1994). As the text progresses, students can refer to and update their models.
- Comprehension monitoring: Teach readers to monitor their comprehension while reading by pausing to reflect on their understanding, clarify confusing points, and adjust their reading strategies as needed. Monitoring comprehension helps good readers stay engaged and actively construct meaning from the text.
How background knowledge powers comprehension
The Science of Reading demonstrates the importance of systematic and explicit phonics instruction. But students don’t have to learn phonics or decoding before knowledge comes into the equation. In fact, the opposite might even be true.
Let’s say you’re handed a passage of text describing part of a baseball game. You read the text, and then you’re asked to reenact that part of the game. Which is most likely to help you do so?
- Your ability to read
- Your knowledge of baseball
- Neither
If you answered “2,” you’re batting 1,000. This example summarizes an influential 1988 study that concluded that the strongest predictor of comprehension was knowledge. In the study, which showed readers (with varying degrees of background knowledge about baseball) a passage describing a game, struggling readers comprehended as well as strong readers—as long as they had prior knowledge of baseball.
“The background knowledge that children bring to a text is also a contributor to language comprehension,” says Sonia Cabell, Ph.D., an associate professor at Florida State University’s School of Teacher Education, on Science of Reading: The Podcast.
In fact, background knowledge is the scaffolding upon which readers build connections between prior knowledge and new words. Students with average reading ability and some background knowledge of a topic will generally comprehend a text on that topic as well as stronger readers who lack that knowledge.
But until recently, literacy instruction has typically focused on decontextualized skills—finding the main idea, making inferences—rather than on the content of texts and resources that students engage with. According to Cabell, what we know about knowledge and comprehension should inform instruction for the whole class. “I think most, if not every, theory of reading comprehension implicates knowledge,” she says. “But that hasn’t necessarily been translated into all of our instructional approaches.”
How can we help build background knowledge while teaching reading? Here are some strategies backed by science.
- Systematically build the knowledge that will become background knowledge. Use a curriculum grounded in topics that build on one another. “When related concepts and vocabulary show up in texts, students are more likely to retain information and acquire new knowledge,” say education and literacy experts Barbara Davidson and David Liben. According to them, this retention even continues into subsequent grades. “Knowledge sticks best when it has associated knowledge to attach to.”
- Provide instruction that engages deeply with content. Research shows that students—and teachers, too—actually find this content-priority approach more rewarding than, in Davidson and Liben’s words, “jumping around from topic to topic in order to practice some comprehension strategy or skill.”
- Support students in acquiring vocabulary related to content. Presenting keywords and concepts prior to reading helps students comprehend text more deeply. Spending more time on each topic helps students learn more topic-related words and more general academic vocabulary they’ll encounter in other texts.
- Use comprehension strategies in service of the content. While building knowledge systematically, teachers can use proven strategies—such as chunking and creating graphic organizers—to help students develop skills they can use to support their for understanding of important information.
- Use discussions and writing to help students learn content. Invite students to share their interpretations, supporting their thought processes in their own words and connecting with peers’ perspectives.
- Help students forge connections in small groups. Help students draw connections between reading lessons and units—and their own experiences—as they grow their knowledge base together.
Every day, the Science of Reading has more to tell us about comprehension as a multifaceted skill that requires a combination of various strategies, tools, and techniques to unlock meaning from text. Because of this body of research, we know that when educators bring intentional and evidence-based practices into the classroom, students can enhance their ability to comprehend grade level text, analyze information critically, and engage with diverse subject areas. By nurturing students’ reading comprehension skills grounded in the Science of Reading, educators can empower students to become good readers who can navigate complex texts with confidence and understanding.
Explore more
The Amplify blog:
Science of Reading: The Podcast
Administrators, welcome to Amplify Science!
Here you’ll find information about enrollment and licensing, technical requirements, professional learning resources, and more.
Onboarding: What to expect
Welcome to Amplify Science! There are six basic steps to onboarding. Use this visual as a reference, but also know that our dedicated implementation team will be there to support you during the entire process.
Technology requirements and guidelines
To ensure that your hardware and network meet the minimum technical requirements for performance and support of your curriculum products, please see Amplify’s customer requirements page.
You’ll also want to add the URLs on this page to the corresponding district- or school-level filters so that your teachers and students can access their Amplify Science materials.
Data sharing agreement
Partnering with Amplify through our data sharing program deepens learning outcomes and gives you the performance analysis you need to make impactful decisions within your district or school. By signing our data sharing agreement, your district will help us to better understand student performance as it relates to your state’s standards. It also allows us to compare results with the curriculum-embedded assessments and state-level assessments. These analyses will help you identify the areas where your teachers and students are excelling or may be experiencing challenges.
Stay tuned for additional updates.
Enrollment and licensing overview
During the enrollment and licensing call, your Amplify implementation partner will walk you through the enrollment process. We recommend exploring the enrollment web tool ahead of the call for suggestions on which enrollment method may be best for your district.
The following guides provide additional information about enrollment methods and the data sharing process.
Preparing for your materials
Each unit of Amplify Science comes with a hands-on materials kit.
Each hands-on materials kit arrives in 1–3 boxes and contains the following:
- Consumable materials
- Nonconsumable materials
- Classroom wall materials
- Premium print materials (cards, maps, etc.)
- 18 copies of each Student Book (K–5)
- A blackline master copy of the Student Investigation Notebook (K–5)
You can find complete materials lists for each unit in the following PDFs. This information is also available in the digital Teacher’s Guide within the program.
Once your district’s purchase order has been sent to Amplify and is processed, Amplify will provide tracking information on your materials kits and any additional print materials you’ve ordered.
Administrator Reports
Self-service Administrator Reports allow insight into teacher and student usage and student performance data for the current school year.
Access is limited to district and school administrators. Administrators can directly access these reports at my.amplify.com/admin-reports.
Announcements
Summer extension
With summer fast approaching, we recognize that some districts may be extending the school year and/or continuing the use of Amplify curriculum and programs for summer instruction. If your summer instruction will continue past June 30 and/or you need to make rostering or enrollment changes, follow our guidance on extending your rollover date.
Use stimulus funding to drive transformation
Learn about ESSER I, II, and III funding (or CARES, CRRSA, and ARP) and how to use these funds to help with learning recovery and acceleration. Districts have significant flexibility in how to use the ESSER money, with ESSER II and III specifying that some of the funds should be used to address unfinished learning. All Amplify programs and services meet the criteria for the funding. Get more information about funding and guidelines.
Next steps: How do I support my teachers?
Pre-launch checklist for teachers
Please share our Program Hub with your educators. It will provide helpful information as they prepare to implement Amplify in their classrooms, including a pre-launch checklist. Note that they’ll need to be logged into Amplify Science to access the Hub. If they don’t have a login yet, you can also download and share the Amplify Science pre-launch checklist for teachers PDF.
Professional learning
We partner with every district to make sure the Amplify Science rollout meets their unique needs. Check out these sample agendas to get a better understanding of what our team has to offer.
Advice and answers
The Science help website is filled with step-by-step resources to address educators’ questions. Encourage your educators to read through these tutorials and search for topics they want to learn more about.
Contact us
Powerful (and free!) pedagogical support
Amplify provides a unique kind of support you won’t find from other publishers. We’ve developed an educational support team of former teachers and administrators who provide pedagogical support at no cost to educators using our programs. This free service includes:
- Information on where to locate standards and other planning materials.
- Recommendations and tips for day-to-day teaching with Amplify Science.
- Support with administering and interpreting assessment data and more.
To reach our pedagogical team, click the orange icon while logged into the curriculum to get immediate help, call (866) 629-2446, or email edsupport@amplify.com.
Timely technical and program support
Our Customer Care and Support team is available Monday through Friday, 7 a.m. to 9 p.m. ET, and Sunday, 10 a.m. to 6 p.m. ET, through a variety of channels:
- Live chat: Click the orange icon while logged into the curriculum to get immediate help in the middle of the school day.
- Phone: Call our toll-free number: (800) 823-1969.
- Email: Send an email to help@amplify.com.
Join our community
Our Amplify Science Facebook group is a community of Amplify Science educators from across the country. It’s a space to share best practices, ideas, and support on everything from implementation to instruction. Join today.
A closer look at grades 3–5
Amplify Science is based on the latest research on teaching and learning and helps teachers deliver age-appropriate, high-quality, literacy-rich instruction that enables students to take on the roles of scientists and engineers to solve real-world phenomena every day.
In the 3–5 classroom, this looks like students:
- Collecting evidence from a variety of sources.
- Making sense of evidence in a variety of ways.
- Formulating convincing scientific arguments.
Program structure
Our cyclical lesson design ensures students receive multiple exposures to concepts through a variety of modalities. As they progress through the lessons within a unit, students build and deepen their understanding, increasing their ability to develop and refine complex explanations of the unit’s phenomenon.
It’s this proven program structure and lesson design that enables Amplify Science California to teach less, but achieve more. Rather than asking teachers to wade through unnecessary content, we designed our 3–5 program to address 100% of the California NGSS in just 88 days.
Scope and sequence
Every year of our grades 3–5 sequence consists of 4 units and 88 lessons. Said another way, each unit contains 20 lessons plus two dedicated assessment days (a Pre-Unit Assessment and End-of-Unit Assessment).
Lessons for grades 3–5 are written to last a minimum of 60 minutes, though teachers can expand or contract the timing to meet their needs.
Unit types
Each unit delivers three-dimensional learning experiences and engages students in gathering evidence from a rich collection of sources, while also emphasizing a particular science and engineering practice.
In grades 3–5:
- One unit emphasizes the practice of investigation.
- One unit emphasizes the practice of modeling.
- One unit emphasizes the practice of engineering design.
- One unit emphasizes the practice of argumentation.
Investigation Units
Investigation units focus on the process of strategically developing investigations and gathering data to answer questions. Students are first asked to consider questions about what happens in the natural world and why, and are then involved in designing and conducting investigations that produce data to help answer those questions.
Modeling Units
Modeling units provide extra support to students engaging in the practice of modeling. Students use physical models, investigate with computer models, and create their own diagrams to help them visualize what might be happening on the nanoscale.
Engineering Design Units
Engineering design units provide opportunities for students to solve complex problems by applying science principles to the design of functional solutions, and iteratively testing those solutions to determine how well they meet preset criteria.
Argumentation units
Argumentation units provide students with regular opportunities to explore and discuss available evidence, time and support to consider how evidence may be leveraged in support of claims, and independence that increases as they mount written arguments in support of their claims.
Units at a glance
Balancing Forces
Domain: Physical Science
Unit type: Modeling
Student role: Engineers
Phenomenon: The town of Faraday is getting a new train that floats above its tracks.
Inheritance and Traits
Domain: Life Science
Unit type: Investigation
Student role: Wildlife biologists
Phenomenon: An adopted wolf in Graystone National Park (“Wolf 44”) has some traits that appear similar to one wolf pack in the park and other traits that appear to be similar to a different wolf pack.
Environments and Survival
Domains: Life Science, Engineering Design
Unit type: Engineering design
Student role: Biomimicry engineers
Phenomenon: Over the last 10 years, a population of grove snails has changed: The number of grove snails with yellow shells has decreased, while the number of snails with banded shells has increased.
Weather and Climate
Domains: Earth and Space Science, Engineering Design
Unit type: Argumentation
Student role: Meteorologists
Phenomenon: Three different islands, each a contender for becoming an Orangutan reserve, experience different weather patterns.
Energy Conversions
Domains: Physical Science, Earth and Space Science, Engineering Design
Unit type: Engineering design
Student role: System engineers
Phenomenon: The fictional town of Ergstown experiences frequent blackouts.
Vision and Light
Domain: Physical Science, Life Science, Engineering Design
Unit type: Investigation
Student role: Conservation biologists
Phenomenon: The population of Tokay geckos in a rain forest in the Philippines has decreased since the installation of new highway lights.
Earth’s Features
Domain: Earth and Space Science
Unit type: Argumentation
Student role: Geologists
Phenomenon: A mysterious fossil is discovered in a canyon within the fictional Desert Rocks National Park.
Waves, Energy, and Information
Domains: Physical Science, Life Science, Earth and Space Science, Engineering Design
Unit type: Modeling
Student role: Marine scientists
Phenomenon: Mother dolphins in the fictional Blue Bay National Park seem to be communicating with their calves when they are separated at a distance underwater.
Patterns of Earth and Sky
Domains: Physical Science, Earth and Space Science
Unit type: Investigation
Student role: Astronomers
Phenomenon: An ancient artifact depicts what we see in the sky at different times — the sun during the daytime and different stars during the nighttime — but it is missing a piece.
Modeling Matter
Domain: Physical Science
Unit type: Modeling
Student role: Food scientists
Phenomenon: Chromatography is a process for separating mixtures. Some solids dissolve in a salad dressing while others do not. Oil and vinegar appear to separate when mixed in a salad dressing.
The Earth System
Domains: Earth and Space Science, Physical Science, Engineering Design
Unit type: Engineering Design
Student role: Water resource engineers
Phenomenon: East Ferris, a city on one side of the fictional Ferris Island, is experiencing a water shortage, while West Ferris is not.
Ecosystem Restoration
Domains:Physical Science, Life Science, Earth and Space Science, Engineering Design
Unit type: Argumentation
Student role: Ecologists
Phenomenon: The jaguars, sloths, and cecropia trees in a reforested section of a Costa Rican rain forest are not growing and thriving.
Resources
Reading and Writing: How the Simple Views can help you teach
The processes of learning to read and write are so complex, they’ve inspired an entire body of research called the Science of Reading (along with its newer cousin, the Science of Writing). Luckily, literacy experts have distilled these processes into their simplest components.
The result? Two models that help educators understand how students learn to read and write, and the best ways to teach them.
These frameworks—the Simple View of Reading and the Simple View of Writing—align with what reading research tells us about the brain’s processes for decoding, understanding, and creating text. Together, they can support your instructional practices and help all your students become proficient readers. Let’s take a closer look.
What is the Simple View of Reading?
The Simple View of Reading is a model that breaks the capacity to read into two main components:
- Decoding: The ability to recognize words in print, which includes phonics and phonemic awareness.
- Language comprehension: The ability to understand and interpret the meaning of those words.
It’s important to note that reading is not the sum of these parts—it’s the product. Reading success results from decoding multiplied by language comprehension. Both are crucial. If either one is weak or nonexistent, the ability to read with understanding collapses. Even if a student can decode every word on a page, they won’t truly be reading if they don’t understand what the words mean. Likewise, no matter how good their comprehension skills, if they can’t decode, they can’t access the text.
Are you curious for more detail? Explore the framework known as the Reading Rope, which breaks these components down further, showing how skills such as phonological awareness, vocabulary, and background knowledge intertwine to create skilled reading. Understanding these connections helps educators develop effective instruction and address specific gaps in literacy skills.
Why is the Simple View of Reading framework so powerful?
The Simple View of Reading gives teachers a clear roadmap.
Instead of wondering why a student is struggling with reading, we can look at their decoding and language comprehension skills separately. Are they having trouble sounding out words? That’s a decoding issue. Struggling to understand a story’s plot? That’s a language comprehension issue.
Once you know where the challenge lies, it’s easier to intervene and teach students effectively.
This model also aligns with the principles of structured literacy. By focusing on explicit, systematic instruction in both decoding and comprehension, educators can build a strong foundation for all learners and support everyone in accessing grade-level text.
The Simple View of Writing: A logical extension
Just as the components of reading can be broken down into two parts, so can writing. They are:
- Transcription: The physical act of writing, including handwriting, spelling, and typing.
- Composition: The ability to generate ideas, organize them, and express them effectively in written form.
Transcription ensures that students can physically put words on a page, while composition helps them turn those words into meaningful text. Writing success equals transcription multiplied by composition. A student may have great ideas (strong composition) but struggle to write them down (weak transcription), or they may write neatly but lack substance.
Putting it together: How these models transform literacy instruction
Reading and writing are closely intertwined. As students improve their decoding, their transcription often follows because both rely on an understanding of letters and sounds. Similarly, language comprehension and composition share a connection—when students build vocabulary and understanding through reading, they’re better equipped to express themselves in writing.
These models allow educators to:
- Pinpoint needs. Are students struggling with spelling? Focus on transcription. Do they have difficulty understanding what they’ve read? Strengthen language comprehension.
- Measure progress. These models provide clear benchmarks for assessing growth. Success in one area (like decoding) can lead to noticeable improvements in another (like comprehension).
- Individualize support. No two students are the same. One child may need help with phonics, while another needs to build vocabulary. The Simple Views let teachers tailor instruction to each learner.
The Simple Views of Reading and Writing remind us that literacy is a combination of distinct yet interconnected skills. By breaking these processes into manageable parts, we can better understand how to help students thrive. And when we focus on both the mechanics and the meaning, we’re not just teaching kids to read and write—we’re giving them the tools to communicate, imagine, and succeed.
More to explore
Check out our infographic for a visual breakdown of these powerful frameworks and how they work together to support literacy success.
Plus:
- Listen: Science of Reading: The Podcast: The Simple View of Reading with Laurence Holt
- Follow @amplify.education on Instagram for reading resources and information
- Read: “Science of Reading principles that guide early literacy”
Hi, educator. Here’s your Step-by-Step Guide to a Quality Curriculum Adoption.
Welcome to the Step-by-Step Guide.
We talked to leaders like you and created this guide to help with the complex process of adopting a high-quality curriculum. You can explore our recommended steps and use the downloadable articles and templates to help with your decision-making process.
You can also download the entire short guide here: Word Doc | PDF
1. Plan your process.
Each step of the process, from assembling a team to preparing materials and socializing the decision, needs to be planned based on your district’s unique needs.
Start with the following case studies if you’d like to see examples from small and mid-sized districts. The worksheets that come next should help you plan the steps in your process and schedule, and the articles provide some ideas for how to assemble your committee.
Links
Case studies:
Worksheets:
Articles:
- Five things to consider as you assemble your team Word Doc | PDF
- Shaping the future: Participating on an adoption committee Word Doc | PDF
2. Define the problem.
Defining the problem shapes your list of requirements and ensures that all involved parties are focused on selecting the right high-quality curriculum.
Links
Worksheet:
3. Build requirements.
Requirements help you prioritize what is most important to your school district and to evaluate why a high-quality curriculum adoption would be the best fit.
Links
Worksheet:
4. Explore programs.
Start with your critical focus areas from step 2 (defining the problem) and select a short list of programs to explore. Next, conduct a thorough review of those programs. If you’re a school or district that pilots, a pilot would happen during this step.
Links
Worksheet:
Articles:
- Getting ready for the review Word Doc | PDF
- Important questions to ask publishers upfront Word Doc | PDF
5. Socialize and evangelize the decision.
You’ve done it! But your work isn’t over. Now you need to create clear, exciting messaging about the high-quality curriculum you’ve chosen and why it’s a good match for your teachers and students.
Links
Article:
Template:
6. Prepare for implementation.
A lot of things happen between signing a purchase order and the first day of professional learning. You’ll want to be organized as you coordinate people, places, and things to get ready for back to school.
Links
Worksheet:
Download the guide.
Our K–12 international education programs inspire students around the world.
At Amplify, we believe that every teacher and student deserves access to high-quality materials. That’s why we collaborate with international schools to meet their core curriculum, assessment, and intervention needs.
By providing solutions grounded in research and evidence-based practices, Amplify is making an impact on international K–12 education.
We are making an impact around the globe.
6
continents
80+
countries
900+
schools worldwide
700,000+
students globally
Amplify international education programs
The following programs are available internationally.
Amplify professional learning
From live, in-person training and coaching to online courses and virtual professional development, we offer a range of support to fit schools’ needs and educators’ busy schedules. Professional development offerings include the following:
- Launch sessions
- Strengthen sessions
- Coach sessions
- Custom packages
Custom development
We collaborate with governments and government agencies to localize and customize our high-quality instructional materials to ensure they align with specific education standards and frameworks.
Get in touch with our sales team to discuss how we can help your organization.
License our digital tools.
Explore Amplify’s digital tools and how they can make your programs more engaging and digital-forward.
Publishers can license the Amplify teaching and learning digital platform, which offers robust digital functionality—including digital manipulatives—that can transform print-based instructional programs into interactive, collaborative, and engaging digital experiences for teachers and students.
If you want to use our platform for commercial purposes, please contact our team.
Amplify international education support
Amplify aims to provide the best customer support throughout each stage of your journey, whether you are exploring our programs for the first time or are a long-term partner.
Below, you’ll find a quick guide on the international purchase process and expected timelines.
Simple steps to get your order processed quickly:
To ensure that there are no delays, we advise you to place your order 3–4 months prior to your first day of school. This should allow enough time for shipping and digital set up.
Purchasing
Our international sales team can answer your questions about our programs and services. Please fill out the form to speak with your account executive.
FILL OUT FORM
Ordering and payment
We want your purchasing experience to be as seamless as possible. Visit our customer portal to learn more about your payment options.
Please be sure to include:
- A signed PO. Don’t forget to add your PO number.
- A copy of your Price Quote.
- A copy of your Tax-Exemption Certificate.
You can also email your documents to IncomingPO@amplify.com.
Shipping physical materials
- Submit your logistics and product quantities on the Order Management Page (OMP).
- Track shipment(s) with the Shipment Status Page (SSP).
Enrollment and licensing
Please note that our team needs to review your school’s rosters for accuracy and completeness:
- This process can take up to 12 business days.
- You will be notified when the licensing process is complete!
Frequently asked questions
Payment processing time can vary, depending on chosen payment method, as well as banking institution. Please allow at least 10 business days for it to be processed. For additional support contact internationalsalessuport@amplify.com.
For digital licenses, you will need to submit your digital logistics information, which includes your school’s rosters data. Our technical onboarding team then needs to verify it for accuracy and completeness. (They might contact you, should they need any clarification.) The digital setup process can take up to four weeks to be completed. For help along the way, please use our Amplify Onboarding Hub.
To avoid delays, please submit your logistics information and product quantities on the Order Management Page as early as possible. Note that international shipping time varies from one country to another due to many factors, including different customs procedures. We are therefore unable to estimate and guarantee delivery time in each case. Amplify offers two international shipping options: 1. Your materials can be shipped from the U.S. directly to you, which will incur an international shipping and handling fee of 25% on the physical products ordered. 2. Alternatively, Amplify can ship your materials to a U.S. freight forwarder, and you can manage the shipping.
Note that setup communications will be sent to the contact person listed on the quote. This email is sometimes routed to the spam folder, so please check there as well. If you do not receive a link within five business days, please reach out to the customer care and support team.
Get support
Our dedicated team members will assist you with purchasing, order fulfillment, enrollment and licensing, and more!
Our support hours are Monday through Friday,
11 a.m.–11 p.m. GMT.
New to our programs? Our international sales support team is here to help!
Email us:
International events
Join us for an upcoming event, webinar, or podcast. You can browse all of our events by month, or use the filter to find events close to you.
Winter Wrap-Up 03: Ideas to build math fluency
Join us for the third episode in our Winter Wrap-Up! In this episode from season 3 of Math Teacher Lounge: The Podcast, we sit down with Dr. Valerie Henry to talk about math fluency and what that means for students. Listen as we dig into the research, hear Val’s three-part definition of fluency, and explore her five principles for developing it.
Explore more from Math Teacher Lounge by visiting our main page.
Dan Meyer (00:03)
Hey folks. Welcome back. This is Math Teacher Lounge, and I am one of your hosts, Dan Meyer.
Bethany Lockhart Johnson (00:07):
And I’m your other host, Bethany Lockhart Johnson. Hi, Dan.
Dan Meyer (00:11):
Hey, great to see you. We have a big one this week to chat about and some fantastic guests. We are chatting about fluency, which is the sort of word and concept that I feel like people have very, very non-neutral associations with it. A lot of them are very negative, for a lot of people.
Bethany Lockhart Johnson (00:26):
I saw you frown a little. What’s up with that, Dan? You kind of, like, shrank.
Dan Meyer (00:30):
I have strong feelings about it. You know, there’s lots of ways that people go about helping people become fluent in mathematics. And a lot of them are harmful for students, and ineffective. And it got me thinking about fluency as it exists outside of the world of mathematics, where we have a lot of very clear images of it. We’re getting fluent in things all the time. Like, as humans. Human development is the story of fluency. And I just was wondering….Bethany, would you describe yourself as fluent at something outside of the world of mathematics? What is that? How’d you get fluent at it? What was the process?
Bethany Lockhart Johnson (01:05):
Hmm, I think I’m a pretty fluent reader. I read all the time. I’m a happier person if I’ve read that day. I once saw this poster in a classroom; it said “10 Ways to Become a Better Reader: Read, Read, Read, Read, Read…you know, 10 times. Get it? Reading? You get better at reading by reading! So I would say reading. And it’s been kind of cool—I have a one-year-old who, it’s been really exciting slash overwhelmingly anxiety-producing to see him get very fluent with walking slash running, ’cause he’s getting faster every day. And it’s kind of fun. When I think of what’s something somebody’s trying to get fluent with…walking! He’s trying to be more fluid. He’s practicing transitions. He doesn’t wanna hold my hand while he traverses rocky terrain. He’s getting better at it. He’s practicing. What about you? What’s something…?
Dan Meyer (02:08):
I think about driving a lot. I’m a very fluent driver and I think a lot about when I was first a driver, you know? And how l have my hands on 10 and 2, vice grip, and do not talk to me; do not ask me anything; don’t ask me my NAME. I need to focus so hard. And then a year later, you know, I’m driving with one hand, smash the turn signal, take a sip off of whatever, change the CD. And then it’s no big deal.
Bethany Lockhart Johnson (02:38):
Wait, did you pass the first time? Your test?
Dan Meyer (02:40):
Yeah, I don’t like to brag about it. <laugh> But I do all the time. <laugh> But I got a hundred on my driving test. I don’t care who knows it. And I hope it’s everybody. But I guess all of this is just to say there are areas of life where fluency feels natural, with the case of walking. There’s areas of life where fluency feels motivating, with like driving—I wanna be able to switch the CD out or whatever. And there’s areas where fluency feels terrifying and hard to come by, like mathematics, sometimes. So we have a set of guests here. Our first guest will help us figure out what do we mean by fluency? And what’s the research say about what fluency is and how students develop it in mathematics? And then our other guests will help us think about what it looks like in practice in the classroom. What are some novel, new ways to work on fluency? So first up we have Val Henry, Dr. Val Henry.
Bethany Lockhart Johnson (03:32):
So we knew we needed help with the fluency definition, because when we think about it, it’s kind of big, right? And we wanted to look at what research about fluency really says. So we called on Valerie Henry. Val is a nationally board-certified teacher, taught middle school for 17 years, and since 2002 has worked with undergraduates graduates, credential candidates as a lecturer at the University of California, Irvine, one of my alma maters. So after doing her dissertation on addition and subtraction fluency in first grade, Val created a project to study ways to build addition and subtraction and multiplication and division fluency while also developing number sense in algebraic thinking. And the pilot grew and grew over the last 18 years into a powerful daily mini-lesson approach to facts fluency called FactsWise. And when we thought of fluency, the first person I thought of was Val. Welcome, Val Henry, to the Lounge! I’m so excited to have you here. Welcome.
Valerie Henry (04:36):
Thanks, Bethany. And thanks to you, Dan. It’s great to be here today.
Dan Meyer (04:41):
Great to have you; help yourself to whatever you find in the fridge. The names that people write down on those things in the bags are just recommendations. It’s potluck-style here. I’m curious, Val, if you’re, like, on an airplane, someone asks you what you do, and you say you study fluency…what is the layperson’s definition of what does it mean to be fluent in mathematics? And if you can give a brief tour through what the research says about what works and what doesn’t that would really help us orient our conversation here.
Valerie Henry (05:12):
The first thing I have to do when I talk to somebody on a plane is define the idea of fluency. And I often use an example of tying your shoelaces. Because that works with first graders as well as adults. This idea that when we first start trying to put our shoes on and get those shoelaces tied, somebody tries to, first of all, just do it for us. But then of course maybe tries to teach us the bunny-ears approach. And we struggle and struggle as little kids and eventually either the bunny-ears approach or something else starts to work for us. But we still have to pay attention to it. We have to think hard and it’s not easy. And then over time we get to the point where we basically don’t even think about it. When I tie my shoes in the morning. I’m not thinking about right-over-left and left-over-right and all of those things. I just do it. And so that’s a good, easy example of becoming fluent with something. I think what we’re talking about today though, is the basics, the adding and subtracting that we hope kids are going to have mastered maybe by second grade, and the multiplication and division facts that we wanna maybe have mastered by third, maybe fourth grade. So now what does that mean to become fluent with those basics? I have a three-part definition that seems to match up really nicely with the common core approach to fluency. Which is, first of all, we want the answers to be correct. And then second, we want the answers to be easy to know. And so what does that mean? Well, to me, it means without needing to count,
Bethany Lockhart Johnson (07:12):
You mean without having to kind of muscle through it? Or say more about you mean.
Valerie Henry (07:16):
Well, I guess what I mean is that when you watch a young child try and solve something even as simple as two plus three, they might put up two fingers and then go 3, 4, 5 with three more fingers winding up on their hand, one or the other of their hands. While they’re doing that, they don’t really have a sense of whether even their answer is right or not, quite often. Especially when you get to the larger adding and subtracting problems, you can see a lot of errors happening as they’re trying to count. And it’s taking up cognitive energy to do that counting process, especially as you get to the larger quantities. So my definition of fluency now is “getting it right without needing to do that hard work like counting.” Now, some people might say, well, we just want them to have ’em memorized. But in my research, I’ve learned that a lot of very fluid adults don’t always have every fact memorized. In fact, if you ask a room full of adults, what’s seven plus nine, you might learn that they can all get it correct quickly, quickly…but they don’t all have it memorized. And so when you ask them, “How did you get that?” Many of them will say, “Well, I just gave one from the 7 to the 9 and I know that 10 plus 6 is 16.”
Bethany Lockhart Johnson (08:53):
That’s such an important distinction. My brain literally just did that actually!
Valerie Henry (08:58):
<laugh> Right? <laugh> But you’re fluid with it, because it doesn’t take you much cognitive energy at all.
Bethany Lockhart Johnson (09:05):
Right.
Valerie Henry (09:07):
So now we have “correct without needing to put that cognitive energy,” which usually means that you’re counting. And then the third thing is “relatively quickly,” so that you’re not spending 15 seconds trying to figure it out. Even that part-whole strategy approach can be done really quickly, almost instantaneously. Or it can take a long time. So if a student can get the answer correct within, you know, three or four seconds— is I’m pretty generous—I figure that they’re pretty darn fluent with that fact. So that’s my three-part definition of these basics, fluency.
Dan Meyer (09:55):
I love the distinction between getting it correct and getting it quick. It’s possible to be quick with wrong answers. It’s possible to be like, “Those are separate components there.” And I echo Bethany’s appreciation for this third option in between knowing it instantaneously through memorization and muscling through it. But there’s like a continuum there of how much energy it took you to come up with it that all feels extremely helpful.
Valerie Henry (10:21):
And you know, one of the things that I’ve noticed is that when kids are pressured to come up with those instantaneous answers, they often default to guessing and get it wrong.
Bethany Lockhart Johnson (10:30):
Mm, yeah.
Valerie Henry (10:30):
So that’s one of the things that I’ve learned is that as we’re trying to help students develop fluency, it’s important to start with building their conceptual understanding of what it means to do, you know, 3 times 9 and what the correct answer is, maybe using manipulatives or representations of some sort. Not skip-counting! I really have found that skip-counting just perpetuates itself in many students’ minds and that they never stop skip-counting, which means they’re putting in not very much mental energy if it’s 2 times 3 but a ton of mental energy if it’s 7 times 8. Because frankly, it’s really hard to skip count by sevens. And by eights.
Bethany Lockhart Johnson (11:18):
I can get to 14 and then I’m like, wait, wait, what was next? Right? No, no, no…21! What do you feel are some misconceptions that maybe teachers, maybe parents have about fluency in math?
Valerie Henry (11:30):
I think maybe one of the first ones is that if students count or skip-count, their answers repetitively over and over and over and over, that they’re bound to memorize them. And the study that I did back in 2004, I actually had a school that had decided that they were going to do time tests with their students every day, all year. And that undoubtedly by the end of the year, those students would be fluent.
Bethany Lockhart Johnson (12:06):
And to clarify by time test, you mean like, sit down, pencil, paper, ready, go, worksheet kind of thing.
Valerie Henry (12:15):
Yes.
Bethany Lockhart Johnson (12:16):
Some of us might remember quite vividly.
Valerie Henry (12:18):
<laugh> Very vividly. And you know, you have to get it done within a certain amount of time. So they made it fun for the students. Apparently the students enjoyed it. I was a little leery about that, but in the end, when I went and checked on the students and I did one-on-one assessments with half of the students in every class that were randomly selected so that I could get a sense of where they were with their fluency—and these were first graders—they basically had nothing memorized. They were simply counting as fast as they possibly could. And, you know, mostly getting the right answers. But they had not memorized. So that’s one of the myths, I think, is that repetitive practice of counting gets you to memorization.
Bethany Lockhart Johnson (13:10):
If I put it in front of you enough times, you’ll become fluent.
Valerie Henry (13:14):
Right, right. Now these students didn’t really get any instruction, any help learning these. They just simply tested over and over and over. So that’s another thing that I think is a misconception. It’s that if we test students, but don’t really teach them fluency, then they’re going to become fluent. If we just test them every Friday or that kind of thing. And that they’ll learn them at home. But really what that means is a few lucky kids who have parents who have the time and the energy and the background to know how to help will take that job on at home. Not that many students are really that fortunate.
Dan Meyer (14:01):
It’s almost like the traditional approach, or the approach you’re describing, confuses process and product. It says, “Well, the product is that eventually fluent students will be able to do something like this, see these problems and answer them, answer them quickly,” and says, “Well, that must be the process then as well; let’s give them that products a whole lot.” But as I hear you describe fluency with bunny ears on shoelaces, there’s these images and approaches and techniques that require a very active teacher presence to support the development of it. That’s just kind of interesting to me.
Valerie Henry (14:35):
My initial project, the pilot project that I tried, was to simply ask teachers to follow five key principles. And the first one was to do something in the classroom every day for—I told them, even if you’ve only got five or 10 minutes, work on fluency for five or 10 minutes a day, and let’s see what happens. So that was one key element was just to teach it and to give students opportunities to get what the research calls for when you’re trying to memorize, which is actually immediate feedback. When I talk about immediate feedback with my student teachers, I say, “I’m talking about within one or two seconds of trying a problem, and then sort of immediately knowing, getting feedback of whether you got the answer right or not so that your brain can kind of gain that confidence. ‘Oh, not only did I come up with an answer, but somebody’s telling me it’s the correct answer.’”
Dan Meyer (15:38):
There’s a lot of apps now in the digital world that offer students questions about arithmetic or other kinds of mathematical concepts and give immediate feedback of a sort: the feedback of “You’re right; you’re wrong” sort. Is that effective fluency development, in your view?
Valerie Henry (15:57):
I haven’t heard and I haven’t seen them being super-effective. The ways I think about this are “Immediate feedback isn’t the only thing we need.” Probably one of the biggest things that we need is for students to develop strategies. And this is one of the other things I’ve learned from international research, from countries that do have students who become very fluent very early, is that they don’t shoot straight for memorization, but they go through this process of taking students from doing some counting and then quickly moving them to trying to use logic. So, “Hey, you really are confident that 2 + 2 is 4; so now let’s use that to think about 2 + 3.” Actually, as an algebra teacher, I would much rather have students that have a combination of memorization and these strategies, than students who’ve only memorized. Isn’t that interesting that my most successful algebra students were good strategy thinkers. Not just good memorizers.
Bethany Lockhart Johnson (17:09):
So you mentioned there were five that kind of helped root this idea in like, “What can teachers do? What is the best thing that teachers can do to support with fact fluency?” So, everyday was key.
Valerie Henry (17:22):
Then the next principle that I really focus on is switching immediately to the connected subtractions so that students—
Bethany Lockhart Johnson (17:33):
Not waiting until you’ve gotten all the way through addition. But making “Ooh!”
Valerie Henry (17:38):
Totally. And I didn’t do that the first year. And when we looked at the results of the assessments at the end of the year, we realized that our students were so much weaker in subtraction than addition. So the following pilot year, we tried this other approach of doing subtraction right after the students had developed some fluency with that small chunk of addition. And we got such better subtraction results.
Bethany Lockhart Johnson (18:11):
What are the other principles?
Valerie Henry (18:13):
The biggest one is to use these strategies. So the strategies makes the third. And then the fourth I would say is to go from concrete to representational to abstract.
Bethany Lockhart Johnson (18:27):
Don’t put away those manipulatives. Don’t put away those tools.
Valerie Henry (18:31):
Oh, so important to come back to them for multiplication and division. And my fifth principle is to wait on assessment. To use it as true assessment, but not race to start testing before students have had a chance to go through this three-phase process. Which is conceptual understanding with manipulatives; building strategies, usually with representations; and then working on building some speed until it’s just that natural fluency.
Bethany Lockhart Johnson (19:07):
I wanna say thank you so much for offering your really learned perspective, because you have not only done the research, but seen it in action and seen how shifting our notions of fluency and what fluency can be and what a powerful foundation it can be for all mathematicians. Really, that shift is so powerful. And I appreciate you sharing it with our listeners and with us. So we’re so excited that we got to talk with you today, Val—
Dan Meyer (19:35):
Thank you, Dr. Henry.
Valerie Henry (19:37):
You’re welcome!
Dan Meyer (19:41):
With us now we have Graham Fletcher and Tracy Zager, a couple of people who understand fluency at a very deep and classroom level. I wanna introduce them and get their perspective on what we’re trying to solve here with fluency. So Graham Fletcher has served in education in a lot of different roles: as a classroom teacher, math coach, math specialist, and he’s continually seeking new and innovative ways to support students and teachers in their development of conceptual understanding in elementary math. He’s the author, along with Tracy, of Building Fact Fluency, a fluency kit we’ll talk about, and openly shares so much of his wisdom and resources at gfletchy.com. Tracy Johnson Zager is a district math coach who loves to get teachers hooked on listening to kids’ mathematical ideas. She is a co-author of this toolkit, Building Fact Fluency, and the author of Becoming the Math Teacher You Wish You’d Had: Ideas and Strategies from Vibrant Classrooms. Tracy also edits professional books for teachers at Stenhouse Publishers, including, yours truly. Thank you for all that insight, Tracy, and support on the book.
Bethany Lockhart Johnson (20:49):
Dan and I were talking at the beginning of the episode about things we feel like, “Hey, I’m fluent in that. I’m fluent in that.”
Dan Meyer (20:55):
Just very curious: What’s something you would like to get fluent in outside of the world of mathematics, let’s say?
Tracy Zager (21:00):
I’ll say understanding the teenage brain, as the parent of a 13-year-old and 15-year-old. That’s the main thing I’m working on becoming fluent in!
Bethany Lockhart Johnson (21:10):
Ooh!
Dan Meyer (21:13):
A language fluency, perhaps. All right, Graham. How about you?
Graham Fletcher (21:16):
For me typing, it’s always been an Achilles heel of mine. So voice-to-text has been my friend. But it’s also been my nemesis in much of my texting here and working virtually over the last couple years. So yeah, typing.
Dan Meyer (21:33):
Do you folks have some way of helping us understand the difference in how fluency is handled by instructors and by learners?
Tracy Zager (21:40):
I would say that the lay meaning of fluency is definitely a little different than what we mean in the math education realm. When we’re talking about math fact fluency, which is just one type of fluency. So you gotta think about procedural fluency and computational fluency; there are lots of types of fluency in math. And Graham and I had the luxury of really focusing in specifically on math fact fluency. We’re looking at kind of a subset of the procedural fluency. So the words you hear in all the citations are accurate, efficient, and flexible. There’s this combination of kids get the right answer in a reasonable amount of time and with a reasonable amount of work and they can match their strategy or their approach to the situation. That’s where that flexibility comes in. And there’s like lots more I wanna say about that about sort of…I think one issue that comes up around fluency is that people are in a little bit of a rush. So they tend to think of the fluency as this automaticity or recall of known facts without having to think about it. And that is part of the end goal, but that’s not the journey to fluency. So this is one of the things that Graham and I thought about a lot was the path to fluency. The goal here it’s that student in middle school who’s learning something new doesn’t have to expend any effort to gather that fact. And they might do it because they’ve done it so many different ways that they’ve got it, and now they just know it, or they might be like my friend who’s a mathematician who still, if you say, “Six times 8,” she thinks in her head, “Twelve, 24, 48…” and she does this double-double-double associative property strategy. And it’s so efficient, you would never know. And that’s totally great. That’s fine. That’s not slowing her down. That’s not providing a drag in the middle of a more complex problem or new learning. So we’re really focused on having elementary school students be able to enter the middle and high school standards without having that pull out of the new thinking.
Graham Fletcher (23:53):
And as I think about that, I think about how so many students will memorize their facts, but then they haven’t memorized them with understanding. So that when they move into middle school and they move into high school, it’s almost like new knowledge and new understanding that’s applied from a stand-alone skill.
Bethany Lockhart Johnson (24:10):
So something that felt really unique to me, Graham, as I was diving into the toolkit, is your use of images, Tracy, Graham, is the way that you use images to help students notice and wonder to start making sense of these quantities and the decomposition of numbers using images. Can you talk a little bit about how images played a part in the way that you think about this building a fact fluency?
Graham Fletcher (24:41):
What I realized is so many times when we approach math with just naked numbers with so many of our elementary students, the numbers aren’t visible. The quantities. They can’t see them; they can’t move them. They’re just those squiggly figures that we were talking about earlier on. So how is it that we make the quantities visible, to where students feel as if they can grab an apple and move it around? Because a lot of times we start with the naked numbers and then if kids don’t get the naked numbers, then we kind of backfill it. But what would happen if we start with the images? And then from there, these rich, flourishing mathematical conversations develop from the images. And I think that was the premise and the goal of the toolkit.
Tracy Zager (25:22):
When you look at how fact fluency has traditionally been taught, it’s all naked numbers. And sometimes we wrote ’em sideways. Like, that’s it. That was our variety of task type. Right? Sometimes it’s vertical; sometimes it’s horizontal. And that was it. And I’ve just known way too many kids who couldn’t find a hook to hang their hat on with that. It didn’t connect to anything. And so part of why I knew Graham was the perfect person for this project was his strength in multimedia photography, art, video. And so we started from this idea of contexts that for each lesson string in the toolkit, there’s some kind of context. An everyday object, arranged in some kind of a way that reveals mathematical structure and invites students to notice the properties. So we start with images of everyday objects: tennis balls, paint pots…um, help me out; here are a million of them. Crayons—
Bethany Lockhart Johnson (26:18):
Crayons, markers.
Tracy Zager (26:18):
Shoes, right? Sushi, origami paper, all kinds of things in the different toolkits. So there’s a series of images or a three-act task or both around those everyday objects, and then story problems grounded in that context. And then there are images with mathematical tools that bring out different ideas, but relate in some way to the image talks. And we do all of that before we get to the naked number talk. Which we do, and by the time you get to the number talk, it’s pretty quick, ’cause they’ve been reasoning about cups of lemonade. And now when you give them the actual numerals, they’re all over it.
Bethany Lockhart Johnson (27:03):
I have to say too, as somebody who—particularly in middle school—navigated math anxiety, we recently talked with Allison Hintz and Anthony Smith about their amazing book Mathematizing Children’s Literature.
Tracy Zager (27:14):
Yay!
Bethany Lockhart Johnson (27:14):
And I was explaining, like, if I sat down at the beginning of a math class and my teacher opened a picture book and said, “We’re gonna start here,” I felt my whole body relax. And if we start with this image, if we start with just looking at an image and making sense of an image, I feel like that could be such a powerful touchstone for all the work you do from there.
Tracy Zager (27:41):
That’s core. That’s a core design principle, is that invitational access. There are no barriers to entry. There’s nothing to decode. There’s nothing formal. We’ve been learning from Dan for years about this, right? Of starting with the informal and then eventually layering in the formal. I was in a class in Maine where they were doing an image talk and it’s these boxes of pencils. It’s a stack of boxes of pencils and they’re open and you can see there are 10 pencils in each box. And so there are five boxes of pencils each with 10 pencils in it. And then the next image is 10 boxes of pencils and each box is half full. So now it’s 10 boxes each with five. And the kids are talking and talking and then the third image, I think there are seven boxes each with 10 pencils in it. And she said, “What do you think the next picture’s gonna be?” And this girl said, “You just never know with these people!” <laugh> I dunno!”
Bethany Lockhart Johnson (28:37):
That’s kinda true. Knowing you both, it’s kinda true.
Tracy Zager (28:42):
Like if it’s seven boxes with 10 in it, one kid said, I think it’s gonna be 14 boxes of five. And other kids are like, I think it’s gonna be 10 boxes with seven. And they start talking about which of those there are and the relationships between—
Bethany Lockhart Johnson (28:58):
But they’re making sense of numbers!
Tracy Zager (28:59):
Totally. So all the kids felt invited. They can offer something up. They’re noticing and wondering about that image. They’re talking about it in whatever informal language or home language that they speak. And that was core to us. That was a huge priority, because honestly, one of the motivations to talk about fluency is that it’s always been this gatekeeper. It has served to keep kids out of meaningful math. Particularly kids from marginalized or historically excluded communities. So they’re back at the round table, doing Mad Minutes, while the more advantaged kids are getting to do rich problem solving. And so, we thought, what if we could teach fact fluency through rich problem solving that everybody could access? That was like square one for us.
Bethany Lockhart Johnson (29:45):
That’s huge.
Dan Meyer (29:46):
That’s great to hear. What’s been helpful for me is to understand that students who are automatic, that’s just kind of what’s on the surface of things. And that below that might be some really robust kind of foundation or scaffolding that bleeds to a larger building being built, or it might be just really rickety and not offer a sturdy place to build farther up. It’s been really exciting to hear that. I wonder if you’d comment for a moment about, in the digital age and—I’m at Desmos and our sponsors are Amplify and we all work in the digital world quite a bit. There are a lot of what report to be solutions to the fluency issue, to developing fluency in the digital world. Just lots and lots of them. Some that are quite well used, others that are just like X, Y, or Z app on the market. You can find something. Do you have perspectives on these kinds of digital fluency building apps? Like, what about them works or doesn’t work? Let us know. Graham, how about you? And then Tracy, I’d love to hear your thoughts too.
Graham Fletcher (30:47):
Yeah, I think that’s a great question, ’cause there’s a lot of shiny bells and whistles out there right now that can really excite a lot of teachers. But I always come back to what works for me as a classroom teacher is probably gonna work in a digital world as well. So what are the things that I love and honor most about being in front of students, and how can I capture that in that virtual world? I think one of the things that really helps students make connections is coherence. I think coherence, especially when you leave students for—you don’t get to talk with them after the lesson is done—so I think about how we can purposefully sequence things through a day-to-day basis. I think coherence is something that gets really lost when we talk about fluency, especially with whether it be digital or whether it be print, because what ends up happening is we say, “OK, we have all these strategies we need to teach,” and it becomes a checklist. So how is it that we can just provide students the opportunity to play around in a space, whether it be digital or in person, but in a meaningful way that allows them the time and the space and that area to breathe and think, but be coherent. And connecting those lessons along the way. And I think coherence is one thing that a lot of the times it’s harder to—when we’re in the weeds, it’s so hard and difficult to zoom back out and say, “Do all these lessons connect? How do they intentionally connect? And how do they purposefully connect?” And without coherence, everything’s kind of broken down into that granular level. So when looking at—I think about Desmos and I think about the Toolkit and I think about how Tracy and I talked a lot about, “Well, this, does it connect with the context problem, does it connect with the image talk, or the lessons? Like, how does it all connect and how are we providing students an opportunity to make connections between the day-to-day instruction and lessons that we tackle?”
Tracy Zager (32:44):
I’m reminded of a conversation that Dan, you and I had a long time ago, in Portland, Maine, in a bar. I’ll just be honest. <laugh> And we were talking about how, in the earlier days of Desmos, you were stressed out by what you saw, which was kids one-on-one, on a device, in a silent room. And you were like, no, this is not it. This is not what technology is here to serve. We can do so many things better using technology appropriately, but we can’t lose talk and we can’t lose relationships and we can’t lose formative assessment and teachers listening to kids and kids listening to each other and helping each other understand their thinking. Right? So when I think about the tech that’s out there for fact fluency, most of it is gonna violate all rules I have around time testing. So that a whole bunch of it, I would just toss on that premise. They’re really no different than flashcards. It’s just flashcards set in junkyard heaps. Or, you know, underground caverns. Or with a volcano or whatever. It’s the same thing. There are some lovely visuals—I’m thinking of Berkeley Everett’s Math Flips. Those are really pretty. Mathigon has some really nice stuff that’s digital. And I think that those resources invite you to kind of ponder and notice things and talk about them. All the tools that we design in the toolkit are designed to get people talking to each other, and give teachers opportunities to pull alongside kids and listen in and understand where they are. For example, our games, we didn’t design the games to be played digitally, even though you could, and people did during COVID, because we want kids on the rug, next to each other, on their knees; I’ve seen kids like across tables. I was in a school recently where a kid was like, “I hope you believe in God, ’cause you’re going…!” You know what I mean? <laugh>. Like they’re all pumped up.
Bethany Lockhart Johnson (34:41):
They’re invested!
Tracy Zager (34:45):
They’re psyching each other up and down and they’re interacting and it’s social and the teacher’s walking around and she’s listening to the games. And they don’t actually need any bells and whistles. They need dice and they need counters and they need this game that is actually a game. In all of our conversations, games have to actually be games. Games cannot be “roll and record.” Games have to involve strategy. They have to be fun. So in designing those games, we didn’t feel like it brought any advantage to make that a digital platform. But things that did bring advantages digitally, like the ability to project these beautiful images or to use short video in the classroom, that really was a value-add that enabled us to do something different in math class than we had done before, and to get kids talking in a different way than they ever had before. When I think about fluency, historically, if you say like, “OK, it’s time to practice our math facts,” you hear a lot of groans. And when I see a Building Fact Fluency classroom and I say, “OK, it’s BFF time!” There’s like a “YEAAAAHHH!” You know? And so that’s what we’re after.
Graham Fletcher (35:47):
It’s all about kids, really, for us. And I think at the heart of it, we made all the decisions with teachers and kids at the forefront of it.
Tracy Zager (35:55):
I know of high schoolers who are newcomers, who have experienced very little formal education, and speak in other languages, are using it as high schoolers, because it involves language and math and all the deep work in the properties and it’s accessible, but it’s also not at all condescending or patronizing. Like we designed it to be appropriate for older kids. So that’s just something that I think we’re both really proud of. One thing we thought a lot about, especially in the multiplication-division kit is how a classroom teacher could use it and a coordinating educator in EL, Title, special education, intervention could also use it because there’s so much in it, that students could get to be experts, if they got extra time in it, using something that’s related and would give them additional practice. So they could play a game a little bit earlier than the rest of the classes. And they could come in already knowing about that game, or they could do a related task. We have all these optional tasks that no classroom teacher would ever have time to teach it all. So the special educator could use it and have kids doing a Same and Different or a True/False, or some of the optional games. And then the work in both special education and general education could connect.
Dan Meyer (37:20):
I just wanna say that this is an area that for so many students, as you’ve said, Tracy, it presents a barrier. It’s a very emotionally fraught area of mathematics. And we really appreciate the wisdom you brought here. And just the care you’ve brought to the product itself. Your knowledge of teaching, knowledge of math, and yeah, especially a love for students feels like it’s really infused throughout Building Fact Fluency. If our listeners want to know more outside of this podcast, outside of the product itself, where can they find your words, your voice? Where you folks at these days? Tell ’em, Graham would you?
Graham Fletcher (37:57):
You can find us at Stenhouse, Building Fact Fluency. And then Tracy and I, currently playing around, sharing ideas a lot on Twitter, under the hashtag #BuildingFactFluency. That’s kind of where we can all come together and share ideas. And then also on the Facebook community, where there’s lots of teachers sharing ideas.
Bethany Lockhart Johnson (38:19):
If you were to ask our listeners like, “Hey, if you wanna keep thinking about this, here’s something you could try or here’s something you could go do,” what could be a challenge that we could share that could help us continue this conversation?
Graham Fletcher (38:35):
Online you can actually download a full lesson string. And a lesson string is a series of activities and resources that are purposefully connected. You can pick one or two of those from the Stenhouse web site, Building Fact Fluency. You can try the game. You can try one of those strategy-based games. You can try an image talk and just see how it goes. And just share and reflect back, whether on Twitter or on Facebook. But it’s kind of there, if you wanna give it a whirl. And as Tracy was sharing, even if you’re a middle-school teacher or a high-school teacher, we really tried to think about those middle-school and high-school students keeping it grade level-agnostic. Just so every student has those opportunities for those mathematical conversations. So download a lesson string and give it a whirl, and we’d love to hear how it goes.
Dan Meyer (39:25):
Bethany and I will be working the same challenge with people in our life.
Bethany Lockhart Johnson (39:29):
Yes.
Dan Meyer (39:29):
Enjoying some fact fluency with people in our homes, perhaps. We’ll see. And we’ll be sharing the results in the Math Teacher Lounge Facebook group. Graham and Tracy, thanks so much for being here. It was such a treat to chat with you both.
Bethany Lockhart Johnson (39:42):
I love learning with you and just helping to shift this idea of fluency into something that can be accessible and powerful and positive.
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Meet the guest
Valerie Henry has been a math educator since 1986. She taught middle school math for 17 years and has worked as a lecturer at University of California Irvine since 2002. After doing her 2004 dissertation research on addition/subtraction fluency in first grade, Valerie created FactsWise, a daily mini-lesson approach that simultaneously develops fluency, number sense, and algebraic thinking. Additionally, she has provided curriculum and math professional development for K-12 teachers throughout her career, working with individual schools, districts, county offices of education, Illustrative Mathematics, the SBAC Digital Library, and the UCI Math Project.
About Math Teacher Lounge: The podcast
Math Teacher Lounge is a biweekly podcast created specifically for K–12 math educators. In each episode co-hosts Bethany Lockhart Johnson (@lockhartedu) and Dan Meyer (@ddmeyer) chat with guests, taking a deep dive into the math and educational topics you care about.
Join the Math Teacher Lounge Facebook group to continue the conversation, view exclusive content, interact with fellow educators, participate in giveaways, and more!
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Discover the captivating journey of writing with our new guide, Science of Writing: A Primer. This resource delves into the history of writing, highlights the crucial link between combining reading and writing instruction, and reveals why handwriting still matters in today’s digital world. Designed to complement CKLA 3rd Edition and our other literacy tools, this primer is set to become a trusted companion, just like those before it.
MTSS Playbook
Explore our new ebook designed to help you build an evidence-based Multi-Tiered System of Supports (MTSS) tailored to diverse literacy goals. This resource provides actionable steps and essential questions to fortify your MTSS with the Science of Reading, enhancing its effectiveness and achieving better outcomes for your students.
The science of teaching reading, coupled with the art of change management
Shifting to the Science of Reading isn’t just an overnight curriculum swap—it’s a profound culture change with multiple stages and stakeholders. We’ve helped educators succeed in that shift for years, and now we’re here to guide you every step of the way. Through each stage of implementation, our Change Management Playbook will help you mobilize your practice, process, and people to make the shift that matters most.
What is the Science of Reading?
Learning to read is not innate, but it can be taught—and science tells us how. The Science of Reading refers to the vast body of growing research that deconstructs how children learn to read, and the instructional practices that can get them there.
Reading fluency requires a complex combination of skills, taught explicitly and systematically. There are two main frameworks that can help us break it all down: The Simple View of Reading and Scarborough’s Rope.
Science of Reading starter kit for new teachers
New to the classroom? We’ve compiled a collection of resources and insights about the Science of Reading to help you acquire more knowledge and build confidence. You’ll find the tools, information, and support you need to foster successful readers and writers in your classroom this school year—and beyond.
The Simple View of Reading
The Simple View of Reading, formulated by Philip Gough and William Tunmer in 1986, is the theory that proficient reading requires two main components:
- Converting written words into speech, otherwise known as decoding.
- Understanding that speech, otherwise known as reading comprehension.
The Reading Rope
The Reading Rope, developed by Dr. Hollis Scarborough in 2001, helps us visualize the strands of specific skills and instruction that support students in decoding and comprehension.
Professional development to support your shift to the Science of Reading
Ignite literacy transformation with Amplify’s Science of Reading: The Learning Lab—an inspiring three-course series.
- Dive into a comprehensive overview with course one, Foundations to the Science of Reading.
- Examine assessments and their roles in course two, Advanced Topics in the Science of Reading: Assessment and Reading Difficulties.
- Apply effective literacy instruction to your classroom in course three, Applied Structured Literacy.
Crafted to the standards of the International Dyslexia Association, this self-paced online series provides unparalleled, research-backed instruction. Explore enriching activities, curated resources, and learn from Susan Lambert, chief academic officer and host of Science of Reading: The Podcast.
The best investment you can make is in knowledge, and the returns are priceless.
Learn more about the online courses or request a quote!
Tap into individual online course seats.
Science of Reading: The Podcast
Tune in to hear the latest insights and trends in early reading, right from leading literacy experts and practitioners.
Listen nowBuild your background knowledge of the Science of Reading.
Our Science of Reading principles and primers explain the essentials: what the Science of Reading is, how it works, and why it matters for every student.
New Science of Reading principles placemat!
Decades of research inform the updated Science of Reading principles placemat. Use these insights as a guide for evidence-based literacy instruction—perfect for committed educators aiming to achieve real improvements in student reading outcomes.
Science of Reading
A Primer: Part 1
In part 1 of our definitive Science of Reading primer, we discuss literacy as a societal goal, walk you through how the brain learns to decode and comprehend text, and present the patterns that top-performing schools and districts follow to achieve early reading success.
Science of Reading
A Primer: Part 2
In part 2 of our Science of Reading primer, we establish the importance of prior knowledge for comprehension, lay out the process of micro-comprehension, and demonstrate how literacy skills build on and accelerate themselves.
“If you’re looking for a Science of Reading training, the [Science of Reading: Foundations to the Science of Reading] online course is great. It helps you build background knowledge on learning how students learn how to read, and then it goes deeper and it gives you strategies that correlate with those findings that you can implement right into your classroom.”
Why undertake this crucial change?
When we bring proven methods based on the Science of Reading into schools, we make sure kids are learning to read and help teachers and caregivers support a culture of reading. Together, we can solve the reading crisis and make literacy a reality everywhere.
You’ll change lives with literacy.
According to the National Assessment of Educational Progress (NAEP), only 35% of fourth graders in the United States are proficient in reading. But schools using a Science of Reading approach have seen significant improvements in literacy rates. Using research-based methods, educators can help give all children the chance to become successful readers.
You’ll build a foundation with explicit, systematic skills instruction.
Reading skills don’t come naturally. We actually need to rewire our brains with intentional, structured literacy instruction—starting with sounds.
You’ll improve outcomes with knowledge building.
Longitudinal research shows that knowledge building doesn’t just happen as a result of reading, but is also a vital prerequisite for and component of it. And when delivered intentionally and systematically, knowledge delivers literacy results.
“It’s not just about the curriculum. It’s about the science behind how people, how children, and how we as humans learn to read… It’s working. I wish I had this years ago. ”
Science of Reading & Early Literacy Resources FAQ
Amplify understands that making the shift to the Science of Reading is no small feat. Get some early literacy resources and guidance with our Science of Reading FAQ.
Learning to read is not innate. It needs to be taught intentionally and systematically—and science tells us how. The vast and growing body of research on early literacy is referred to as the Science of Reading. It draws on extensive research in cognitive science, linguistics, and neuroscience. It emphasizes the systematic teaching of foundational skills—such as phonics, phonological awareness, and decoding—in building vocabulary and comprehension. In other words, it deconstructs the processes behind how children learn to read, and provides evidence for the instructional practices and early literacy resources that can get them there.
The Science of Reading refers to the pedagogy and practices proven by extensive research to effectively teach children how to read. It places a strong emphasis on both components of the Simple View of Reading, demonstrating that systematic and explicit instruction in phonics and and intentionally sequenced knowledge building are critical to reading success.
In a balanced literacy environment, learning happens through reading and writing immersion, where the need for explicit instruction in phonics is recognized but is not the primary focus.
The key difference between the approaches lies in their emphasis on foundational reading skills and a coherent approach to building language comprehension.
A balanced literacy approach typically includes a combination of whole language approaches (emphasizing meaning and context) and phonics instruction. Balanced literacy instruction is designed to be flexible and open to interpretation by the instructor. It may include the three-cueing system, which encourages students to rely on syntactic and semantic clues in a text to read an unfamiliar word, rather than decoding (Does it look right? Does it sound right? Does it make sense?). Balanced literacy practitioners may also use leveled reading to differentiate instruction, which can can limit vocabulary exposure, hinder in-depth comprehension skills, and further widen achievement gaps.
Balanced literacy has long been a popular approach to reading instruction, with educators appreciating its openness to variation. But advocates for the Science of Reading argue that an evidence-based approach aligned with known cognitive processes and a focus on foundational skills and language comprehension provides the most solid foundation for reading instruction—for confident and struggling readers alike.
According to our friends at The Reading League, the Science of Reading is important not because it gives us an effective way to teach reading, but because it gives us the most effective way to teach reading.
“The Science of Reading is critical because it emphasizes evidence-based instruction. Decades of scientific research on reading have consistently shown the most effective ways to teach reading. The Science of Reading incorporates this research, which includes phonemic awareness, phonics, fluency, vocabulary, and comprehension.”
The Reading League also takes it to the next level: What happens when all children have access to the most effective early literacy and reading education? “We believe in a future where a collective focus on applying the Science of Reading through teacher and leader preparation, classroom application, and community engagement will elevate and transform every community, every nation, through the power of literacy.”
The Science of Reading has identified five foundational reading skills that are considered crucial for early reading development. One of those skills is phonics. In other words, the Science of Reading has established that phonics are crucial, but the Science of Reading is not the same as phonics.
Phonics instruction helps students learn how to sound out and blend letters to read words accurately. As we know from the Simple View of Reading, two fundamental skills are required for reading with comprehension:
- Decoding—the ability to recognize written words (via phonics)
- Language comprehension—understanding what words mean
And the Science of Reading also reminds us that students do not have to learn phonics or decoding before knowledge comes into the equation. “The background knowledge that children bring to a text is also a contributor to language comprehension,” says Sonia Cabell, Ph.D., associate professor at Florida State University’s School of Teacher Education, on Science of Reading: The Podcast.
The Science of Reading is an evolving field built on decades of high-quality, evidence-based research that continually integrates new insights gathered from cognitive neuroscience, psychology, and linguistics. These ongoing studies constantly refine our understanding of how the human brain processes language and learning, enabling more personalized and effective teaching strategies that can adapt to the wide-ranging learning needs of students.
Like other sciences such as medicine, astronomy, or engineering – new advancements in reading technology allow us to understand how the brain works and refine our practices. Every scientific advancement in this field of reading science deepens our comprehension of reading-related challenges like dyslexia and informs the development of evidence-based interventions. We don’t believe that the Science of Reading can be reduced to a fad or trend. Rather, it is a continually evolving, enduringly effective discipline, grounded in rigorous research and driven by the quest for better comprehension of how we read and learn.
Assessment grounded in the Science of Reading can help identify children at risk of dyslexia at the earliest possible moments, creating the widest opportunity for intervention.
People with dyslexia often experience challenges in phonological awareness. They may struggle to break down words into their component sounds and to recognize the relationships between letters and sounds. Systematic and explicit instruction in phonics and phonological awareness can help individuals with dyslexia develop necessary phonological skills. This evidence-based instruction can also help students who have difficulty with decoding.
Further, evidence-based comprehension instruction, including explicit instruction in vocabulary and comprehension strategies, can support students with dyslexia in understanding and making meaning from text.
The Science of Reading can be integrated with a Multi-Tiered System of Supports (MTSS) to provide comprehensive and targeted reading instruction for all students. The Science of Reading aligns with a tiered model by providing evidence-based practices for instruction at each tier. An MTSS includes universal screening to identify students at risk of reading difficulties; the Science of Reading can also guide the selection of screening measures to assess specific foundational skills. Aligning the Science of Reading with an MTSS framework can also enhance instructional practices and interventions, ensure data-driven decision making, and help meet the needs of all students.
Integrating the Science of Reading and the Science of Writing strengthens our approach to teaching literacy. Reading and writing are interdependent. Understanding how sentences are built not only contributes to better reading comprehension, it also helps writers develop clear, logical text. As students grow as readers, they also grow as writers, leading to a comprehensive literacy education. Clear thinking and effective writing are crucial for expressing ideas. By fostering both skills, teachers better support students in becoming confident readers and writers, prepared for academic challenges and beyond.
One of the research-based frameworks used in the Science of Reading is the Simple View of Reading. According to the Simple View, two cognitive capacities are needed for proficient reading: (1) understanding the language (comprehension) and (2) recognizing words in print (decoding). A true Science of Reading program is designed from the start for students to build these skills, in a developmentally appropriate way.
It will also emphasize the importance of knowledge building by exposing students to a diverse array of new topics spanning history, science, and literature, organized intentionally and coherently within and across grades. Deep and intentionally sequenced knowledge domains will help build a student’s vocabulary and understanding of complex texts. And it will include instruction in all five foundational skills: phonics, phonemic awareness, vocabulary, fluency, and comprehension.
Download our free ebook, Science of Reading: Making the Shift, which includes a checklist of what to look for in a curriculum based on the Science of Reading. Learn more from our friends at The Reading League.
Actually, we have a full literacy suite built on the Science of Reading! It includes:
- mCLASS® assessment, powered by DIBELS® 8th Edition, a gold-standard universal and dyslexia screener, plus a progress monitoring tool, all in one.
- Amplify Core Knowledge Language Arts (CKLA), which provides explicit, systematic foundational skills instruction combined with intentional knowledge building.
- Boost Reading, a highly adaptive personalized reading program that reinforces the core curriculum and supports enrichment, remediation, and intervention for each student in your classroom.
- mCLASS Intervention, a staff-led intervention program targeted to Tiers 2 and 3, made easy with automatic data-driven grouping and sequenced explicit, systematic skills lesson plans to support at-risk students.
Reading requires deliberate, systematic attention—and so does shifting to the Science of Reading in your school or district. It requires not only the right curriculum, but also all-new mindsets, metrics, and more. Reflecting years of experience supporting real educators, our resources will walk you through the process of change management in your community—and show you why the shift is worth it. View our Science of Reading change management playbook.
Overview Video
The Lawrence Hall of Science
Developed by the science education experts at UC Berkeley’s Lawrence Hall of Science and the digital learning team at Amplify, our program features:
- A phenomena-based approach where students construct a complex understanding of each unit’s anchor phenomenon.
- A blend of cohesive storylines, hands-on investigations, rich discussions, literacy-rich activities, and digital tools.
- Carefully crafted units, chapters, lessons, and activities designed to deliver true 3-dimensional learning.
- An instructional design that supports all learners in accessing all standards.
Instructional model
The Amplify Science program is rooted in the proven, research-based pedagogy of Do, Talk, Read, Write, Visualize. Here’s how each element works:
DO
First-hand investigations are an important part of any science classroom, and Amplify Science has students getting hands-on in every unit—from building models of protein molecules to experimenting with electrical systems.
TALK
Student-to-student discourse and full-class discussions are an integral part of the program. Students are provided with numerous opportunities to engage in meaningful oral scientific argumentation, all while fostering a collaborative classroom environment.
READ
Students read scientific articles, focusing their reading activities on searching for evidence related to their investigation and, importantly, on asking and recording questions as they read through fascinating texts on 21st-century topics.
WRITE
Following real-world practices, students write scientific arguments based on evidence they’ve collected, making clear their reasoning about how a given piece of evidence connects to one of several claims.
VISUALIZE
By manipulating digital simulations and using modeling tools to craft visualizations of their thinking— just as real scientists and engineers do—students take their learning far beyond the confines of what they can physically see in the classroom in an exciting and authentic way.
Program structure
Our cyclical lesson design ensures students receive multiple exposures to concepts through a variety of modalities. As they progress through the lessons within a unit, students build and deepen their understanding, increasing their ability to develop and refine complex explanations of the unit’s phenomenon.
It’s this proven program structure and lesson design that enables Amplify Science to address 100% of the NGSS, and support students in mastering the standards.
Unit types
While every unit delivers three-dimensional learning experiences and engages students in gathering evidence from a rich collection of sources, each unit also serves a unique instructional purpose.
In grades 6–8:
- One unit is a launch unit.
- Three units are core units.
- Two units are engineering internships.
Launch units are the first units taught in each year of Amplify Science. The goal of the Launch unit is to introduce students to norms, routines, and practices that will be built on throughout the year, including argumentation, active reading, and using the program’s technology. For example, rather than taking the time to explain the process of active reading in every unit in a given year, it is explained thoroughly in the Launch unit, thereby preparing students to read actively in all subsequent units.
Core units establish the context of the unit by introducing students to a real-world problem. As students move through lessons in a Core unit, they figure out the unit’s anchoring phenomenon, gain an understanding of the unit’s disciplinary core ideas and science and engineering practices, and make linkages across topics through the crosscutting concepts. Each Core unit culminates with a Science Seminar and final writing activity.
Engineering Internship units invite students to design solutions for real-world problems as interns for a fictional company called Futura. Students figure out how to help those in need, from tsunami victims in Sri Lanka to premature babies, through the application of engineering practices. In the process, they apply and deepen their learning from Core units.
Unit sequence
Our lessons follow a structure that is grounded in regular routines while still being flexible enough to allow for a variety of learning experiences.
In fact, our multi-modal instruction offers more opportunities for students to construct meaning, and practice and apply concepts than any other program. What’s more, our modular design means our units can be flexibly arranged to support your instructional goals.
Program components
Available digitally and in print, our unit-specific reference guides are chock full of helpful resources, including scientific background knowledge, planning information and resources, color-coded 3-D Statements, detailed lesson plans, tips for delivering instruction, and differentiation strategies.
Hands-on learning is an essential part of Amplify Science, and is integrated into every unit. Students actively participate in science, playing the roles of scientists and engineers as they gather evidence, think critically, solve problems, and develop and defend claims about the world around them. Every unit includes hands-on investigations that are critical to achieving the unit’s learning goals.
More hands-on with Flextensions:
Hands-on Flextensions are additional, optional investigations that are included at logical points in the learning progression and give students an opportunity to dig deeper if time permits. These activities offer teachers flexibility to choose to dedicate more time to hands-on learning. Materials referenced in Hands-on Flextension activities will either be included in the unit kit or are easily sourced. Supporting resources such as student worksheets will be included as downloadable PDF files.
Our kits include enough materials to support 200 student uses. In other words, teachers can easily support all five periods and small groups of 4-5 students each. Plus, our unit-specific kits mean teachers just grab the tub they need and then put it all back with ease.
Our digital Simulations and Practice Tools are powerful resources for exploration, data collection, and student collaboration. They allow students the ability to explore scientific concepts that might otherwise be invisible or impossible to see with the naked eye.
Available for every unit, our Student Investigation Notebooks contain instructions for activities and space for students to record data and observations, reflect on ideas from texts and investigations, and construct explanations and arguments.
In grades 6–8, one copy of the Student Investigation Notebook is included in each unit’s materials kit for use as a blackline master. Each notebook is also available as a downloadable PDF on the Unit Guide page of the digital Teacher’s Guide.
These customizable PowerPoints are available for every lesson of the program and make delivering instruction a snap with visual prompts, colorful activity instructions, investigation set-up videos and animations, and suggested teacher talk in the notes section of each slide.
Explore your print samples
With your Amplify Science print samples, you’ll find unit-specific Teacher’s References Guides and Student Investigation Notebooks for each grade level.
A note about the Teacher’s Reference Guides:
It’s important that your committee sees the full breadth and depth of our instruction. For that reason, we provided a copy of each of our unit-specific Teacher Reference Guides.
Rest assured that teachers do not use these robust reference guides for day-to-day teaching. For that, we have a hands-free TG!
- Teacher Reference Guide: Unlike a typical TG that requires a series of supplemental books to support it, our encyclopedic reference guide is chock-full of everything a teacher needs to fully implement our program and the NGSS.
- Ready-to-Teach Lesson Slides: For daily instruction, teachers need their hands free. That’s why we created ready-to-teach lesson slides for every single lesson. What’s more, they are editable and include suggested teacher talk and point-of-use differentiation and other instructional tips. Click to learn more.
A note about the Materials Kits:
Hands-on learning is at the heart of Amplify Science, and is integrated into every unit. In order to make hands-on learning more manageable for busy teachers, Amplify Science materials are organized into unit-specific kits.
Our unit-specific kits:
- Include more materials — We give teachers enough materials to support 200 student uses.
- Are more manageable — Unlike other programs that require large groups of students to share limited sets of materials, our kits include enough to support small groups of 4–5 students.
- Include supportive videos — Each hands-on activity provides clear instructions for the teacher, with more complex activities supported by video demonstrations and illustrations.
What comes in each grade level kit? Click the links below to see the grade-specific lists of all materials included in each kit.
Access your digital samples
Explore as a teacher
Follow these instructions to explore the Amplify Science digital platform as a teacher.
- Click the Access Amplify Science Platform button below and bookmark it.
- Select Log in with Amplify.
- Enter the username: t1.jeffersoncounty@demo.tryamplify.net
- Enter the password: Amplify1-jeffersoncounty
- Click the Science icon.
- Click on the Program Menu in the top center of the screen and select any grade.
- Select any unit.
To help familiarize yourself with navigating the digital platform,watch the below navigational video.
Explore as a student
Follow these instructions to explore the Amplify Science digital platform as a student.
- Click the Access Amplify Science Platform button below and bookmark it.
- Select Log in with Amplify.
- Enter the username: s1.jeffersoncounty@demo.tryamplify.net
- Enter the password: Amplify1-jeffersoncounty
- Click the Science icon.
- Click on the Grade Menu in the top center of the screen and select any grade.
- Select any unit.
Resources to support your review
Amplify and SFUSD Partnership
We recognize and respect the unique differences of each of our partnering districts—and that includes San Francisco USD.
Out of the box, Amplify Caminos offers districts a rich, comprehensive, research-based SELA experience. That said, no two districts are exactly alike. To that end, we are committed to working with San Francisco USD to ensure that Amplify Caminos addresses the needs of your community. This includes providing implementation guidance and support, as well as collaborating with your staff to determine which domains need to be modified or exchanged.
What is Amplify Caminos?
Amplify Caminos is a core Spanish language arts program for grades TK–5 that delivers:
- Authentic instruction built from the ground up for the Spanish language.
- A unique research-based approach truly built on the Science of Reading.
- A combination of explicit foundational skills with meaningful knowledge-building.
- Embedded support and differentiation that gets all students reading grade-level texts together.
- Opportunities for students to see the strengths and experiences that all people share while also celebrating each others’ unique identities and experiences.
Watch the video below to learn more about Amplify Caminos for Grades K–2.
Watch the video below to learn more about Amplify Caminos for Grades 3–5.
How does Amplify Caminos work?
Amplify Caminos is built on the science of how kids learn to read—in Spanish.
Amplify Caminos is all about helping you teach students how to read, all while giving them authentic and engaging reasons to read. That’s why Amplify Caminos develops foundational skills and builds knowledge in tandem.
- Knowledge: Through complex and authentic Spanish read-alouds with an emphasis on classroom interactivity, oral comprehension, and contextual vocabulary, students start to build their awareness of the world around them—and the way the reading skills they’re building give them access to it.
- Skills: Starting with the sounds at the core of the Spanish
language, students practice their phonemic awareness, handwriting skills, vocabulary, spelling, and grammar. Through daily practice, students become aware of the connection between reading and writing, building confidence as they go.
Respecting the development differences between grade ranges, Amplify Caminos teaches foundational skills and background knowledge as two distinct strands in grades K–2, and combines them into one integrated strand in grades 3–5.
Grades K–2:
Every day, students in grades K–2 complete one full lesson that explicitly and systematically builds foundational reading skills in the Amplify Caminos Lectoescritura strand, as well as one full lesson that builds robust background knowledge to access complex text in the Amplify Caminos Conocimiento strand. Through learning in each of these strands, students develop the early literacy skills necessary to help them become confident readers and build the context to understand what they’re reading.
Grades 3–5:
In grades 3–5, the Amplify Caminos Lectoescritura and Conocimiento strands are integrated in one set of instructional materials. Lessons begin to combine skills and knowledge with increasingly complex texts, close reading, and a greater writing emphasis. Students can then use their skills to go on their own independent reading adventures.
What do Amplify Caminos students explore?
Amplify Caminos builds students’ knowledge about the world.
In addition to teaching all students to crack the written code (which is vital for equity), the Amplify Caminos program helps students see the strengths and experiences we all share while celebrating their own unique identities and experiences.
This is accomplished through the exploration of topics and text that feature people who resemble students and familiar situations or experiences while also exposing them to people whose appearances, lives, beliefs, and backgrounds differ from their own.
Engaging domains
Amplify Caminos builds knowledge coherently across subjects and grades.
Throughout the program, students use their skills to explore domains that relate to storytelling, science, and the history of our world as seen through the eyes of many different groups.
Carefully selected to build from year-to-year, our grade-appropriate topics help students make and deepen connections while also reading, writing, and thinking creatively and for themselves.
New Knowledge Research Units for Grades K–5
Our brand-new Knowledge Research units carry forward Amplify Caminos’ powerful and proven instructional approach while also:
- Adding more diversity. The rich topics and highly visual components featured in these units provide students with even more “windows and mirrors” and perspectives as they work to build knowledge.
- Adding more authentic literature. Each new research unit revolves around a collection of high-interest authentic trade books that will spark more curiosity and inspire more inquiry.
- Adding more flexibility. Units can be implemented for extended core instruction during flex periods, district-designated Pausing Points, or enrichment periods.
Units cover a variety of rich and relevant topics:
With these new units, students will soar to new heights with Dr. Ellen Ochoa, Amelia Earhart, and the Tuskegee Airmen. They’ll feel the rhythm as they learn about Jazz legends Miles Davis, Tito Puente, and Duke Ellington. And they’ll explore the far reaches of the world with Jacques Cousteau, Matthew Henson, and Eugenie Clark.
- Grade K: El arte y el mundo que nos rodea
- Grade 1: Cuentos de aventuras: relatos desde los confines de la Tierra
- Grade 2: ¡A volar! La era de la aviación
- Grade 3: Jazz y más
- Grade 4: Energía: pasado, presente y futuro
- Grade 5: Más allá de Juneteenth: de 1865 al presente
Units will be made available in English and Spanish, and will include the following components:
Why we added this unit:
“Every child is an artist,” said Picasso, meaning that every child uses art to explore and understand the world around them. El arte y el mundo que nos rodea honors that truth by introducing Kindergarten students to some of the ways in which artists have explored and understood the world around them.
This domain introduces students to artists from different time periods, countries, and cultures. Throughout the unit, students learn about different kinds of art and how artists use the world around them as they make art. They also connect this to what they have already learned about the earth, plants, and animals in other Caminos domains: Granjas, Plantas, and Cuidar el planeta Tierra. In addition, students connect this to what they have learned about sculptors in the Presidentes y símbolos de los Estados Unidos domain. As they explore different artists and artistic traditions, they develop their ideas about how humans are connected to each other and to the world around them.
As you read the texts in this unit, students may observe ways in which the characters or subjects are both similar to and different from students. This is a good opportunity to teach students awareness and sensitivity, building on the idea that all people share some things in common, even as they have other things that make them unique. This unit also offers an excellent opportunity to collaborate with your school’s art teacher, as many lessons have suggested activities to help students understand the kind of art they are studying.
Within this unit, students have opportunities to:
- Use details to describe art.
- Identify three ways to create art.
- Identify characteristics of cave art.
- Sequence the steps of making pottery.
- Describe how artists can create work connected to the world around them.
- Describe what makes Kehinde Wiley’s portraits unique.
- Explain how the texture of a surface can affect artwork created on it.
- Explain what a sculpture is.
- Describe what makes James Turrell’s artwork about the sky unique.
- Explain what a museum is and what kinds of things you can see or do there.
Trade books in this unit:
Instruction in this unit revolves around the following collection of high-interest authentic trade books. One copy of each trade book is included with the unit materials.
- Georgia O’Keeffe por Erica Salcedo
- Yayoi Kusama: De aquí al infinito por Sarah Suzuki
- Tejedora del arcoíris por Linda Elovitz Marshall
- Las tijeras de Matisse por Jeanette Winter
- El museo por Susan Verde
- Quizás algo hermoso: Cómo el arte transformó un barrio por F. Isabel Campoy
Sample materials:
Take a sneak peek at the rich instruction and engaging activities for this unit by viewing the PDFs below.
Why we added this unit:
This domain introduces students to adventure stories set around the world and challenges students to dig into the adventures through research. By listening to the Read-Alouds and trade books, students increase their vocabulary and reading comprehension skills, learn valuable lessons about perseverance and teamwork, and become familiar with gathering information for research.
In this unit, students study the careers of real-world explorers Dr. Eugenie Clark and Sophia Danenberg, marvel at the inventions of Jacques Cousteau, think critically about how teamwork and collaboration can make greater adventures possible, learn about the science and technology that enable adventures, and research some of the ways humans have confronted challenges at the edges of the world, from the oceans below to space above.
Each lesson in the domain builds students’ research skills as they ask questions, gather information, and write a paragraph about their findings. Students share what they have learned about adventures in an Adventure Gallery Walkthrough. By taking on the persona of one of the adventurers they meet in the Read-Alouds and trade books, students deliver their final paragraphs as if they are a “speaking portrait” of that person. Students are invited to dress up as that adventurer if they desire.
In addition, teachers can set aside time outside the instructional block to create the picture frames students will hold as they present to the Adventure Gallery Walk guests. Frames can be made from shirt boxes, cardboard, construction paper, or any art supplies that are on hand. This might be an opportunity to collaborate with the school’s art department if resources are available. Another option is to ask students to make their frames at home with their caregivers. On the day of the Adventure Gallery Walk, students will be the hosts and take on specific jobs, such as welcoming the guests, describing their work throughout the unit, and pointing out the areas of study on the domain bulletin board. You can find a complete list of student jobs in Lesson 13.
How this unit builds knowledge:
This unit builds upon the following Caminos units that students will have encountered in the previous grade.
- Rimas y fábulas infantiles (Kindergarten)
- Cuentos (Kindergarten)
The specific core content targeted in these domains is particularly relevant to the Read-Alouds students will hear in Cuentos de aventuras: relatos desde los confines de la Tierra. The background knowledge students bring to this unit will greatly enhance their understanding of the trade books used in this unit.
Trade books in this unit:
Instruction in this unit revolves around the following collection of high-interest authentic trade books. One copy of each trade book is included with the unit materials.
- My Name Is Gabito/Me llamo Gabito por Monica Brown
- Galápagos Girl/Galapagueña por Marsha Diane Arnold
- My Name Is Gabriela/Me llamo Gabriela por Monica Brown
- El viaje de Kalak por María Quintana Silva y Marie-Noëlle Hébert
- Señorita Mariposa por Ben Gundersheimer
- Sharuko, el arqueólogo peruano/Peruvian Archaeologist Julio C. Tello por Monica Brown
- Abuelita fue al mercado por Stella Blackstone
Sample materials:
Take a sneak peek at the rich instruction and engaging activities for this unit by viewing the PDFs below.
- Guía del maestro: Cuentos de aventuras: relatos desde los confines de la Tierra
- Cuaderno de actividades: Cuentos de aventuras: relatos desde los confines de la Tierra
- Tarjetas de imágenes: Cuentos de aventuras: relatos desde los confines de la Tierra
- Componentes digitales: Cuentos de aventuras: relatos desde los confines de la Tierra
Why we added this unit:
With this domain, students head up, up, and away with an introduction to the soaring history of aviation. Students learn the stories of early aviators, such as the Montgolfier brothers, the Wright brothers, Aida de Acosta, and Amelia Earhart.
During the unit, students study the science of flight, including the physics concept of lift, and research the social impacts of the world of flight. Finally, students let their research skills take flight as they explore key figures from the world of aviation.
The lessons in this domain build on earlier Grade 2 Caminos domains about the westward expansion, early Greek civilizations, and Greek myths, and lay the foundation for learning about other periods of world history in future grades.
How this unit builds knowledge:
This unit builds upon the following Caminos units that students will have encountered earlier in the year.
- La civilización griega antigua (Grade 2)
- Mitos griegos (Grade 2)
- La expansión hacia el oeste (Grade 2)
The specific core content targeted in these domains is particularly relevant to the Read-Alouds students will hear in ¡A volar! La era de la aviación. The background knowledge students bring to this unit will greatly enhance their understanding of the trade books used in this unit.
Trade books in this unit:
Instruction in this unit revolves around the following collection of high-interest authentic trade books. One copy of each trade book is included with the unit materials.
- ¡A volar! Todo sobre aviones por Jennifer Prior
- Amelia sabe volar por Mara dal Corso
- Héroes de la aviación que cambiaron el mundo por Dan Green
- El niño que alcanzó las estrellas por José M. Hernández
- La niña que aprendió a volar por Sylvia Acevedo
- Buenas Noches Capitán Mamá por Graciela Tiscareño-Sato
Sample materials:
Take a sneak peek at the rich instruction and engaging activities for this unit by viewing the PDFs below.
Why we added this unit:
This domain teaches students about the vibrant music, poetry, and culture of the Jazz Age in the United States. Students learn about famous writers and musicians like Langston Hughes, Louis Armstrong, Billie Holiday, Melba Liston, Tito Puente, and Miles Davis. They study how the jazz art form took root in the South, then spread to the North to become the sound of the Harlem Renaissance, eventually connecting people around the world in musical expression.
During this unit, students perform guided research to further explore both the history of jazz and what jazz is today. They develop research skills and then use those skills to find deeper connections between the stories and music of the Jazz Age and music today. As students learn about the world of jazz, they collaborate and share ideas with their classmates. They also practice sharing feedback focused on their written work, and, at the end of the unit, students present their research to the group.
The lessons give students opportunities to dive into the rhythms and stories of jazz, utilizing the knowledge sequence in this unit to:
- Collaboratively generate research questions about jazz, jazz musicians, contemporary musicians from the state where they live or have lived, and the evolution of jazz music.
- Utilize Read-Alouds, independent reading, and partner reading to learn about the Jazz Age, the Harlem Renaissance, jazz music, and biographies of celebrated jazz musicians and writers.
- Research the answers to their generated questions, gather information, write a short research essay about a famous jazz musician, write a short essay about a contemporary musician from the state where they live or have lived, and give a presentation about their research.
How this unit builds knowledge:
Within this unit, students have opportunities to:
- Ask relevant questions and make pertinent comments
- Identify details in texts
- Determine key ideas of texts by evaluating details
- Make text-based inferences
- Generate questions based on prior knowledge and gathered information
- Synthesize details across texts to demonstrate comprehension
- Discuss and explain an author’s purpose
- Identify and cite reliable primary and secondary sources of information
- Compose a well-organized and focused informative essay
- Make connections between topics
- Present information using appropriate media
Trade books in this unit:
Instruction in this unit revolves around the following collection of high-interest authentic trade books. One copy of each trade book is included with the unit materials.
- ¡Esquivel! Un artista del sonido de la era espacial por Susan Wood
- Ray Charles por Sharon Bell Mathis
- Tito Puente, el Rey del Mambo por Monica Brown
- Me llamo Celia, la vida de Celia Cruz por Monica Brown
- ¡Azúcar! por Ivar Da Coll
In this unit, students also read the poem “Harlem” by Langston Hughes. (Available for free through the Academy of American Poets website and the Poetry Foundation website, with recorded audio available through the website for John Hancock College Preparatory High School.)
Sample materials:
Take a sneak peek at the rich instruction and engaging activities for this unit by viewing the PDFs below.
Why we added this unit:
With this domain, students become tomorrow’s problem solvers in this study of energy in the United States. Analytical reading skills are developed by examining the challenges of early energy innovators. Students then read about current energy practices and young energy change-makers across the world.
Throughout the unit, students conduct research into different sources of energy and present a proposal, putting them in the shoes of future energy innovators. They also use the knowledge sequence in this unit to:
- Collaboratively analyze texts to identify cause-effect and problem-solution relationships.
- Generate questions and conduct research about energy.
- Write an opinion essay making their case for a fuel of the future.
- Create energy proposals using primary and secondary resources.
How this unit builds knowledge:
This unit builds upon the following Caminos units that students will have encountered in previous grades as well as earlier in the year.
- Plantas (Grade K)
- La historia de la Tierra (Grade 1)
- ¡Eureka! Estudiante inventor (Grade 4)
The specific core content targeted in these domains is particularly relevant to the Read-Alouds students will hear in Energía: pasado, presente y futuro. The background knowledge students bring to this unit will greatly enhance their understanding of the trade books used in this unit.
Trade books in this unit:
Instruction in this unit revolves around the following collection of high-interest authentic trade books. One copy of each trade book is included with the unit materials.
- La historia de los combustibles fósiles por William B. Rice
- El niño que domó el viento por William Kamkwamba y Bryan Mealer
Sample materials:
Take a sneak peek at the rich instruction and engaging activities for this unit by viewing the PDFs below.
Why we added this unit:
Within this domain, Students learn about General Granger’s announcement in Galveston, Texas on June 19, 1865, a day marked in history as Juneteenth. Texts and multimedia sources will support foundational knowledge-building about the end of slavery in the United States. A review of the first freedom announcement, President Lincoln’s Emancipation Proclamation, provides students with background knowledge to further emphasize the significance of Juneteenth in American history.
This unit also takes students on a journey beyond Juneteenth, as they study specific contributions of African Americans from 1865 to the present day. Students participate in a virtual field trip to Emancipation Park in Houston, Texas and use the knowledge sequence in this unit to:
- Collaboratively generate research questions about Juneteenth, The Great Migration, innovators and inventors, education, the humanities, activists, and allies.
- Use Read-Alouds, independent, and partner reading to learn about African American contributions from 1865 to the present.
- Research to find answers to their generated questions, gather information, and write a four-chapter Beyond Juneteenth book.
How this unit builds knowledge:
This unit builds upon the following Caminos units that students will have encountered in previous grades.
- Los nativos americanos (Grade K)
- Una nueva nación: la independencia de los Estados Unidos (Grade 1)
- La Guerra Civil de los Estaods Unidos (Grade 2)
- La inmigración (Grade 2)
- Los nativos americanos (Grade 5)
The specific core content targeted in these domains is particularly relevant to the Read-Alouds students will hear in Más allá de Juneteenth: de 1865 al presente
. The background knowledge students bring to this unit will greatly enhance their understanding of the trade books used in this unit.
Trade books in this unit:
Instruction in this unit revolves around the following collection of high-interest authentic trade books. One copy of each trade book is included with the unit materials.
- Martí’s Song for Freedom/Martí y sus versos por la libertad escrito por Emma Otheguy
- ¡Celebremos Juneteenth! escrito por Carole Boston Weatherford
- Side by Side/Lado a Lado: The Story of Dolores Huerta and Cesar Chavez/La Historia de Dolores Huerta y César Chávez escrito por Monica Brown
- Canto de alabanza para el día: Poema para la ceremonia inaugural del mandato de Barack Obama escrito por Elizabeth Alexander, traducido por Rodrigo Rojas
Sample materials:
Take a sneak peek at the rich instruction and engaging activities for this unit by viewing the PDFs below.
Diverse texts
Amplify Caminos puts a variety of texts in the hands of students every day.
Amplify Caminos includes both transadaptations and authentic texts written by Latin American and Spanish authors. In addition to featuring a diverse range of authors and topics, our texts represent individuals and characters with a broad range of identity factors, including socioeconomic status, age, ability, race, ethnicity, country of origin, religion, and more.
Amplify Caminos texts include:
- Authentic literature: Authentic literature exposes students to a variety of text types and perspectives to deepen their knowledge of fascinating topics in social studies, science, literature, and the arts. Authentic texts support text-to-self, text-to-world, and text-to-text connections for readers.
- Decodable Student Readers: Amplify Caminos is built on the conviction that equitable instruction is vital to an effective program. Decodable Student Readers at grades K–2 are newly re-designed to celebrate students’ diverse experiences and feature individuals with a broad range of identity factors, including socioeconomic status, age, ability, race, ethnicity, country of origin, religion, and more.
- ReadWorks® texts: Amplify and ReadWorks have partnered to deliver high-quality texts curated to support the Amplify Caminos Knowledge Sequence and to extend student learning. Texts include high-interest nonfiction articles in topics in social studies, science, literature, and the arts. These texts are accompanied by vocabulary supports and standards-aligned formative assessment opportunities. Teachers can monitor their students’ progress using the ReadWorks reporting features.
Amplify Caminos Trade Book Collection Guide
Each book in our authentic literature collection was selected specifically to support and enhance the content of the K-2 Conocimiento Strand. These anchor texts are intended for use as an introduction to each domain—engaging students, piquing their curiosity, and building initial background knowledge—before diving into the deeper content of the domain Read-Alouds.
Every trade book has an instructional guide that includes the following:
- Author and illustrator
- Book summary
- The Essential Question of the Knowledge domain, connecting the book to the domain
- Key Tier 2 and Tier 3 vocabulary words found in the book
- A group activity to reinforce and extend students’ knowledge and understanding
- A performance task to help gauge students’ comprehension of concepts in the text
- Writing prompts to expand understanding and critical thinking
- Text complexity ratings and descriptors for quantitative, qualitative, and reader/task categories
Download the Amplify Caminos Trade Book Collection Guide for Grades K–2.
Detailed information about text complexity ratings and descriptors; additional uses for the books before, during, and after domain instruction; and the complete list of domains and books for each grade level can be found in the More About the Books section of this guide.
What makes Amplify Caminos different?
Built on the Science of Reading
Built out of the latest research in the Science of Reading, Amplify Caminos delivers explicit instruction in both foundational literacy skills (systematic phonics, decoding, and fluency) and background knowledge in grades K–2 with an integrated approach to explicit instruction in grades 3–5.
Explicit systematic skills instruction
The skills instruction in Amplify Caminos was distinctly developed with the Spanish language in mind. Its foundational lessons are specific to the language, rather than a direct translation from Amplify CKLA’s English skills instruction.
Reading instruction begins with the vowels first, then the most common consonants, and finally the least common consonants. Students will blend and segment sounds to form syllables, and syllables to form words.
Although Spanish has a highly predictable orthography, there are a few silent letters (h is always silent, u is silent after g or q), as well as letters that can make different sounds, depending on the letters that follow them. For that reason, syllables with these letters are taught somewhat later in the progression. The same is true for syllables with infrequently occurring consonants, such as z, k, x, and w.
Coherent knowledge instruction
While students are learning how to read, the Conocimiento strand gives them authentic and engaging reasons to read.
Amplify Caminos uses spiral learning to reinforce every student’s ability to develop skills like reading, writing, speaking, and listening in Spanish that can be transferred to English. As students engage with their lessons, they explore the similarities and differences in grammar, vocabulary, writing, and language use between Spanish and English. This bridge helps students learning two languages to strengthen their knowledge in both.
Through cross-curricular content, students explore units that relate to storytelling, science, and the history of our world in a holistic and thoughtful way. With these units, you’ll bring the world to your students, showing them how reading can become an exciting, rewarding, and useful part of their lives.
Embedded differentiation for all learners
Amplify Caminos provides built-in differentiation strategies and supports in every lesson.
- Apoyo a la enseñanza y desafío: Support and Challenge suggestions in every lesson provide assistance or opportunities for more advanced work toward the goal of the lesson.
- Notas culturales: These point-of-use notes provide additional information about the traditions, foods, holidays, word variations, and more from across the Spanish-speaking world.
- Apoyo adicional: Every lesson in the Lectoescritura (Skills) Strand provides additional support activities suggested to reinforce foundational skills instruction. These activities can be given to any student who requires extra help, including students with special needs.
Systematic and cohesive writing instruction
Writing instruction in Amplify Caminos builds systematically and cohesively within and across grades.
In Grades K-2, writing mechanics—including handwriting and spelling—are taught in the Amplify Caminos Lectoescritura strand. Starting in Grade 1, instruction includes four steps in the writing process: planning, drafting, editing, and publishing and features lessons that have modeling, collaboration, and sharing. As students gain skills and confidence, they are able to take on more of these steps independently. Students learn to use planning techniques, including brainstorming and graphic organizers.
Beginning in Grade 4, the Amplify Caminos writing process expands to also include sharing and evaluating. In Grades 4 and 5, the writing process is no longer conceptualized as a series of scaffolded, linear steps (an important change from the Grade 3 writing process). Rather, students move between components of the writing process in a flexible manner, similar to the process mature and experienced writers follow naturally.
Amplify Caminos’ writing instruction provides a clear progression through the text types in each grade.
Because Amplify Caminos has two strands of lessons in Grades K-2, Lectoescritura and Conocimiento, students are exposed to both narrative and informational texts throughout the year. In Grades 3-5, the integrated units feature study in literary, informational, or a mix of both types of texts, depending on the content of the unit.
- Grades K–2 introduce and establish the key elements of each text type, allowing students to gain comfort and confidence writing narratives, opinions, and informative texts. This enables students to practice thinking about content in different ways, offering more depth and breadth to their understanding of core content and of the writing text types.
- By Grade 3, students will have gained significant practice in narrative, opinion/argumentative, and informational/explanatory forms of writing and will continue to apply those skills through Grade 5.
How does Amplify Caminos integrate with the other parts of the literacy system?
Amplify Caminos + mCLASS® Lectura
Achieve complete parity between English and Spanish assessments with mCLASS Lectura for K–6. mCLASS Lectura allows teachers to connect with their Spanish-speaking students face-to-face, one-on-one, and in the language most comfortable to them. The result? Valid and reliable student data reports
available in both English and Spanish, enabling teachers to pinpoint where their Spanish-speaking or emergent bilingual students really are in their skill development and what instruction to prioritize.
Amplify Caminos + Amplify Reading
Amplify Reading is an engaging, adaptive digital program that extends the learning in Amplify Caminos. Amplify Reading offers support to a large sub-group of English learners (ELs) through Spanish voice-over. Spanish voiceover instructions are available in vocabulary and sentence-level comprehension games so ELs can build their vocabulary, language, and critical comprehension skills before moving into analyzing complex texts
Demo access and sample materials
Ready to explore on your own? First, watch the videos below to learn about the program’s components and how to navigate the digital platform.
Physical materials walkthrough video
Digital navigation video
Demo access
Next, follow the instructions below to access your demo account.
- Click the CKLA and Caminos Demo button below.
- Select Log in with Amplify.
- To explore as a teacher, enter this username: t1.sfusdreviewer@demo.tryamplify.net
- To explore as a student, enter this username: s1.sfusdreviewer@demo.tryamplify.net
- Enter the password: Amplify1-sfusdreviewer
- Click the Programs and apps menu
- Select CKLA Teacher Resource Site
- Select the desire grade level
- Use the toggle to switch between English (CKLA) and Spanish (Caminos) resources.
Sample materials
Finally, click on the grade levels below to explore your requested sample units.
Each book in our authentic literature collection was selected specifically to support and enhance the content of the K-2 Conocimiento Strand. These anchor texts are intended for use as an introduction to each domain—engaging students, piquing their curiosity, and building initial background knowledge—before diving into the deeper content of the domain Read-Alouds.
Every trade book has an instructional guide that includes the following:
- Author and illustrator
- Book summary
- The Essential Question of the Knowledge domain, connecting the book to the domain
- Key Tier 2 and Tier 3 vocabulary words found in the book
- A group activity to reinforce and extend students’ knowledge and understanding
- A performance task to help gauge students’ comprehension of concepts in the text
- Writing prompts to expand understanding and critical thinking
- Text complexity ratings and descriptors for quantitative, qualitative, and reader/task categories
Download the Amplify Caminos Trade Book Collection Guide for Grades K–2.
Detailed information about text complexity ratings and descriptors; additional uses for the books before, during, and after domain instruction; and the complete list of domains and books for each grade level can be found in the More About the Books section of this guide.
Conocimiento Strand:
- Guía del maestro, Conocimiento 12: Luchar por una causa
- Cuaderno de actividades, Conocimientos 7–12
- Rotafolio de imágenes, Conocimiento 12
- Tarjetas de imágenes, Conocimiento 12
Lectoescritura Strand:
Additional resources
- Caminos Program Guide
- Biliteracy and Science of Reading Principles
- Amplify Caminos Conocimiento Scopes and Sequences
- Grade K Knowledge Strand
- Grade 1 Knowledge Strand
- Grade 2 Knowledge Strand
- Grade 3 Integrated Strand
- Grade 4 Integrated Strand
- Grade 5 Intgrated Strand
Welcome, Florida community reviewers!
From full operation to lasting change with the Science of Reading: Phase 3
Welcome to the third and final installment in our series about the change management required to make the shift to the Science of Reading in your schools.
In Phase 1 of this series, we answered the question: Why is the Science of Reading important? We also described its potential to deliver literacy transformation—both in your classrooms and districts, and nationwide.
Change at that level requires hard work at your level, starting with what those in the field often call “exploration.” In Phase 1, we discussed what teachers should know about the Science of Reading. You established the rationale for changing to a Science or Reading curriculum and built buy-in from stakeholders.
In Phase 2 of this series, we guided you in evaluating Science of Reading programs, helping you answer the question: Which program will best help your school or district transition to the evidence-based practices that will drive results for students? We also walked through the selection, adoption, and initial implementation of Science of Reading resources.
And now you’re ready for change management Phase 3: full operation, innovation, and sustainability. What does this phase look like? How will the Science of Reading be used effectively? Where and how will you see student growth? Read on for all this and more.
Phase 3, part 1: Full operation
At this stage, Science of Reading literacy practices are fully integrated throughout your system.
Remember, the three key drivers of educational change are process, practice, and people. So let’s break the full operation phase down into these categories:
Process
Conduct routine data analysis to monitor student progress and determine areas of needed improvement.
Practice
Expand the focus on evidence-based literacy practice to other grade-level instructional areas to support the integration of these practices into the larger system (when appropriate). That might include personalized learning, intervention, support for bilingual students, and others.
People
Plan and implement onboarding processes for new teachers and administrators. Emphasize deeper understanding of resources and instructional practices through continuous improvement, coaching, and mentoring.
Questions to answer at this stage:
- How has the integration of evidence-based practices and resources impacted literacy development of students?
- What specific progress-monitoring processes are in place to track the effectiveness of literacy practices?
- Are interventions effective for students not reading on grade level?
- Have we reduced the number of students who are at risk?
- How are staff onboarded and prepared to step into the system?
- What ongoing professional learning will occur?
Phase 3, part 2: Innovation and sustainability
All these phases, all this work—here’s where it starts to pay off.
With Science of Reading practices fully in play, you’ll see them start to work in the form of student growth.
This stage will allow for refinement of instructional practice and a much deeper understanding of how Science of Reading research affects student achievement.
This is also a moment to continue building knowledge by focusing on middle school. Your middle schoolers need to draw on the foundational skills built in earlier grades—or get the intervention that will help them catch up—and build an academic knowledge base that will prepare them for success in high school and beyond. Continuing to bring research-based literacy practices to middle school instruction will help them get there.
And now, your final set of the 3 Ps:
Process
- Leave room for innovation aligned with the ever-growing body of Science of Reading research.
- Consider creating processes that will allow for the expansion of pedagogy based on the Science of Reading into middle schools.
Practice
- Ensure that current research and data are informing instructional decisions and continuing to deepen the knowledge base you’ve built so far.
- Implement systems such as collaborative conversations about data, peer-to-peer instructional rounds, and the study of problems of practice to support deeper implementation.
- Develop professional learning systems and put them into practice.
People
- Emphasize a culture of collaboration and shared ownership, as well as a community of practice.
- Focus conversations on student growth and outcomes to better allocate resources.
Question to answer at this stage:
- What strategies and systems can we develop to encourage innovation while remaining true to the implementation of chosen resources?
Now you have the tools, the plan, and the motivation to help drive life-changing results and improve literacy outcomes for all students by bringing the Science of Reading into your classrooms. We’re happy to be part of that change. And we’d love to hear how it goes!
More ways to explore:
- Creating change that lasts when implementing the Science of Reading: Phase 1
- Adopting and implementing the right Science of Reading program: Phase 2
- Managing the change that matters most: Implementing the Science of Reading with integrity
- The Science of Reading
- Change Management Playbook
- Change management principles
- Science of Reading: A New Teacher’s Guide ebook
Amplify Caminos for SFUSD
Amplify Caminos is an authentic elementary Spanish language arts program. Like its English language counterpart, Amplify CKLA, Amplify Caminos provides explicit, systematic foundational skills instruction sequenced with deep knowledge-building content to foster comprehension. When used with Amplify CKLA, Amplify Caminos provides full parity across English and Spanish that’s suitable for any dual language implementation model.
Amplify and SFUSD Partnership
We recognize and respect the unique differences of each of our partnering districts—and that includes San Francisco USD.
Out of the box, Amplify Caminos offers districts a rich, comprehensive, research-based SELA experience. That said, no two districts are exactly alike. To that end, we are committed to working with San Francisco USD to ensure that Amplify Caminos addresses the needs of your community. This includes providing implementation guidance and support, as well as collaborating with your staff to determine which domains need to be modified or exchanged.
What is Amplify Caminos?
Amplify Caminos is a core Spanish language arts program for grades TK–5 that delivers:
- Authentic instruction built from the ground up for the Spanish language.
- A unique research-based approach truly built on the Science of Reading.
- A combination of explicit foundational skills with meaningful knowledge-building.
- Embedded support and differentiation that gets all students reading grade-level texts together.
- Opportunities for students to see the strengths and experiences that all people share while also celebrating each others’ unique identities and experiences.
Watch the video below to learn more about Amplify Caminos for Grades K–2.
Watch the video below to learn more about Amplify Caminos for Grades 3–5.
How does Amplify Caminos work?
Amplify Caminos is built on the science of how kids learn to read—in Spanish.
Amplify Caminos is all about helping you teach students how to read, all while giving them authentic and engaging reasons to read. That’s why Amplify Caminos develops foundational skills and builds knowledge in tandem.
- Knowledge: Through complex and authentic Spanish read-alouds with an emphasis on classroom interactivity, oral comprehension, and contextual vocabulary, students start to build their awareness of the world around them—and the way the reading skills they’re building give them access to it.
- Skills: Starting with the sounds at the core of the Spanish
language, students practice their phonemic awareness, handwriting skills, vocabulary, spelling, and grammar. Through daily practice, students become aware of the connection between reading and writing, building confidence as they go.
Respecting the development differences between grade ranges, Amplify Caminos teaches foundational skills and background knowledge as two distinct strands in grades K–2, and combines them into one integrated strand in grades 3–5.
Grades K–2:
Every day, students in grades K–2 complete one full lesson that explicitly and systematically builds foundational reading skills in the Amplify Caminos Lectoescritura strand, as well as one full lesson that builds robust background knowledge to access complex text in the Amplify Caminos Conocimiento strand. Through learning in each of these strands, students develop the early literacy skills necessary to help them become confident readers and build the context to understand what they’re reading.
Grades 3–5:
In grades 3–5, the Amplify Caminos Lectoescritura and Conocimiento strands are integrated in one set of instructional materials. Lessons begin to combine skills and knowledge with increasingly complex texts, close reading, and a greater writing emphasis. Students can then use their skills to go on their own independent reading adventures.
What do Amplify Caminos students explore?
Amplify Caminos builds students’ knowledge about the world.
In addition to teaching all students to crack the written code (which is vital for fairness), the Amplify Caminos program helps students see the strengths and experiences we all share while celebrating their own unique identities and experiences.
This is accomplished through the exploration of topics and text that feature people who resemble students and familiar situations or experiences while also exposing them to people whose appearances, lives, beliefs, and backgrounds differ from their own.
Engaging domains
Amplify Caminos builds knowledge coherently across subjects and grades.
Throughout the program, students use their skills to explore domains that relate to storytelling, science, and the history of our world as seen through the eyes of many different groups.
Carefully selected to build from year-to-year, our grade-appropriate topics help students make and deepen connections while also reading, writing, and thinking creatively and for themselves.
New Knowledge Research Units for Grades K–5
Our brand-new Knowledge Research units carry forward Amplify Caminos’ powerful and proven instructional approach while also:
- Adding more content for students from all walks of life. The rich topics and highly visual components featured in these units provide students with even more “windows and mirrors” and perspectives as they work to build knowledge.
- Adding more authentic literature. Each new research unit revolves around a collection of high-interest authentic trade books that will spark more curiosity and inspire more inquiry.
- Adding more flexibility. Units can be implemented for extended core instruction during flex periods, district-designated Pausing Points, or enrichment periods.
Units cover a variety of rich and relevant topics:
With these new units, students will soar to new heights with Dr. Ellen Ochoa, Amelia Earhart, and the Tuskegee Airmen. They’ll feel the rhythm as they learn about Jazz legends Miles Davis, Tito Puente, and Duke Ellington. And they’ll explore the far reaches of the world with Jacques Cousteau, Matthew Henson, and Eugenie Clark.
- Grade K: El arte y el mundo que nos rodea
- Grade 1: Cuentos de aventuras: relatos desde los confines de la Tierra
- Grade 2: ¡A volar! La era de la aviación
- Grade 3: Jazz y más
- Grade 4: Energía: pasado, presente y futuro
- Grade 5: Más allá de Juneteenth: de 1865 al presente
Units will be made available in English and Spanish, and will include the following components:
- Teacher Guide
- Student Activity Books
- Image Cards
- Trade Book Collection
- Digital Components (for Grades K–3 and Grade 5 only)
Why we added this unit:
“Every child is an artist,” said Picasso, meaning that every child uses art to explore and understand the world around them. El arte y el mundo que nos rodea honors that truth by introducing Kindergarten students to some of the ways in which artists have explored and understood the world around them.
This domain introduces students to artists from different time periods, countries, and cultures. Throughout the unit, students learn about different kinds of art and how artists use the world around them as they make art. They also connect this to what they have already learned about the earth, plants, and animals in other Caminos domains: Granjas, Plantas, and Cuidar el planeta Tierra. In addition, students connect this to what they have learned about sculptors in the Presidentes y símbolos de los Estados Unidos domain. As they explore different artists and artistic traditions, they develop their ideas about how humans are connected to each other and to the world around them.
As you read the texts in this unit, students may observe ways in which the characters or subjects are both similar to and different from students. This is a good opportunity to teach students awareness and sensitivity, building on the idea that all people share some things in common, even as they have other things that make them unique. This unit also offers an excellent opportunity to collaborate with your school’s art teacher, as many lessons have suggested activities to help students understand the kind of art they are studying.
Within this unit, students have opportunities to:
- Use details to describe art.
- Identify three ways to create art.
- Identify characteristics of cave art.
- Sequence the steps of making pottery.
- Describe how artists can create work connected to the world around them.
- Describe what makes Kehinde Wiley’s portraits unique.
- Explain how the texture of a surface can affect artwork created on it.
- Explain what a sculpture is.
- Describe what makes James Turrell’s artwork about the sky unique.
- Explain what a museum is and what kinds of things you can see or do there.
Trade books in this unit:
Instruction in this unit revolves around the following collection of high-interest authentic trade books. One copy of each trade book is included with the unit materials.
- Georgia O’Keeffe por Erica Salcedo
- Yayoi Kusama: De aquí al infinito por Sarah Suzuki
- Tejedora del arcoíris por Linda Elovitz Marshall
- Las tijeras de Matisse por Jeanette Winter
- El museo por Susan Verde
- Quizás algo hermoso: Cómo el arte transformó un barrio por F. Isabel Campoy
Sample materials:
Take a sneak peek at the rich instruction and engaging activities for this unit by viewing the PDFs below.
- Guía del maestro: Cuentos de aventuras: relatos desde los confines de la Tierra
- Cuaderno de actividades: Cuentos de aventuras: relatos desde los confines de la Tierra
- Tarjetas de imágenes: Cuentos de aventuras: relatos desde los confines de la Tierra
- Componentes digitales: Cuentos de aventuras: relatos desde los confines de la Tierra
Why we added this unit:
This domain introduces students to adventure stories set around the world and challenges students to dig into the adventures through research. By listening to the Read-Alouds and trade books, students increase their vocabulary and reading comprehension skills, learn valuable lessons about perseverance and teamwork, and become familiar with gathering information for research.
In this unit, students study the careers of real-world explorers Dr. Eugenie Clark and Sophia Danenberg, marvel at the inventions of Jacques Cousteau, think critically about how teamwork and collaboration can make greater adventures possible, learn about the science and technology that enable adventures, and research some of the ways humans have confronted challenges at the edges of the world, from the oceans below to space above.
Each lesson in the domain builds students’ research skills as they ask questions, gather information, and write a paragraph about their findings. Students share what they have learned about adventures in an Adventure Gallery Walkthrough. By taking on the persona of one of the adventurers they meet in the Read-Alouds and trade books, students deliver their final paragraphs as if they are a “speaking portrait” of that person. Students are invited to dress up as that adventurer if they desire.
In addition, teachers can set aside time outside the instructional block to create the picture frames students will hold as they present to the Adventure Gallery Walk guests. Frames can be made from shirt boxes, cardboard, construction paper, or any art supplies that are on hand. This might be an opportunity to collaborate with the school’s art department if resources are available. Another option is to ask students to make their frames at home with their caregivers. On the day of the Adventure Gallery Walk, students will be the hosts and take on specific jobs, such as welcoming the guests, describing their work throughout the unit, and pointing out the areas of study on the domain bulletin board. You can find a complete list of student jobs in Lesson 13.
How this unit builds knowledge:
This unit builds upon the following Caminos units that students will have encountered in the previous grade.
- Rimas y fábulas infantiles (Kindergarten)
- Cuentos (Kindergarten)
The specific core content targeted in these domains is particularly relevant to the Read-Alouds students will hear in Cuentos de aventuras: relatos desde los confines de la Tierra. The background knowledge students bring to this unit will greatly enhance their understanding of the trade books used in this unit.
Trade books in this unit:
Instruction in this unit revolves around the following collection of high-interest authentic trade books. One copy of each trade book is included with the unit materials.
- My Name Is Gabito/Me llamo Gabito por Monica Brown
- Galápagos Girl/Galapagueña por Marsha Diane Arnold
- My Name Is Gabriela/Me llamo Gabriela por Monica Brown
- El viaje de Kalak por María Quintana Silva y Marie-Noëlle Hébert
- Señorita Mariposa por Ben Gundersheimer
- Sharuko, el arqueólogo peruano/Peruvian Archaeologist Julio C. Tello por Monica Brown
- Abuelita fue al mercado por Stella Blackstone
Sample materials:
Take a sneak peek at the rich instruction and engaging activities for this unit by viewing the PDFs below.
Why we added this unit:
With this domain, students head up, up, and away with an introduction to the soaring history of aviation. Students learn the stories of early aviators, such as the Montgolfier brothers, the Wright brothers, Aida de Acosta, and Amelia Earhart.
During the unit, students study the science of flight, including the physics concept of lift, and research the social impacts of the world of flight. Finally, students let their research skills take flight as they explore key figures from the world of aviation.
The lessons in this domain build on earlier Grade 2 Caminos domains about the westward expansion, early Greek civilizations, and Greek myths, and lay the foundation for learning about other periods of world history in future grades.
How this unit builds knowledge:
This unit builds upon the following Caminos units that students will have encountered earlier in the year.
- La civilización griega antigua (Grade 2)
- Mitos griegos (Grade 2)
- La expansión hacia el oeste (Grade 2)
The specific core content targeted in these domains is particularly relevant to the Read-Alouds students will hear in ¡A volar! La era de la aviación. The background knowledge students bring to this unit will greatly enhance their understanding of the trade books used in this unit.
Trade books in this unit:
Instruction in this unit revolves around the following collection of high-interest authentic trade books. One copy of each trade book is included with the unit materials.
- ¡A volar! Todo sobre aviones por Jennifer Prior
- Amelia sabe volar por Mara dal Corso
- Héroes de la aviación que cambiaron el mundo por Dan Green
- El niño que alcanzó las estrellas por José M. Hernández
- La niña que aprendió a volar por Sylvia Acevedo
- Buenas Noches Capitán Mamá por Graciela Tiscareño-Sato
Sample materials:
Take a sneak peek at the rich instruction and engaging activities for this unit by viewing the PDFs below.
Why we added this unit:
This domain teaches students about the vibrant music, poetry, and culture of the Jazz Age in the United States. Students learn about famous writers and musicians like Langston Hughes, Louis Armstrong, Billie Holiday, Melba Liston, Tito Puente, and Miles Davis. They study how the jazz art form took root in the South, then spread to the North to become the sound of the Harlem Renaissance, eventually connecting people around the world in musical expression.
During this unit, students perform guided research to further explore both the history of jazz and what jazz is today. They develop research skills and then use those skills to find deeper connections between the stories and music of the Jazz Age and music today. As students learn about the world of jazz, they collaborate and share ideas with their classmates. They also practice sharing feedback focused on their written work, and, at the end of the unit, students present their research to the group.
The lessons give students opportunities to dive into the rhythms and stories of jazz, utilizing the knowledge sequence in this unit to:
- Collaboratively generate research questions about jazz, jazz musicians, contemporary musicians from the state where they live or have lived, and the evolution of jazz music.
- Utilize Read-Alouds, independent reading, and partner reading to learn about the Jazz Age, the Harlem Renaissance, jazz music, and biographies of celebrated jazz musicians and writers.
- Research the answers to their generated questions, gather information, write a short research essay about a famous jazz musician, write a short essay about a contemporary musician from the state where they live or have lived, and give a presentation about their research.
How this unit builds knowledge:
Within this unit, students have opportunities to:
- Ask relevant questions and make pertinent comments
- Identify details in texts
- Determine key ideas of texts by evaluating details
- Make text-based inferences
- Generate questions based on prior knowledge and gathered information
- Synthesize details across texts to demonstrate comprehension
- Discuss and explain an author’s purpose
- Identify and cite reliable primary and secondary sources of information
- Compose a well-organized and focused informative essay
- Make connections between topics
- Present information using appropriate media
Trade books in this unit:
Instruction in this unit revolves around the following collection of high-interest authentic trade books. One copy of each trade book is included with the unit materials.
- ¡Esquivel! Un artista del sonido de la era espacial por Susan Wood
- Ray Charles por Sharon Bell Mathis
- Tito Puente, el Rey del Mambo por Monica Brown
- Me llamo Celia, la vida de Celia Cruz por Monica Brown
- ¡Azúcar! por Ivar Da Coll
In this unit, students also read the poem “Harlem” by Langston Hughes. (Available for free through the Academy of American Poets website and the Poetry Foundation website, with recorded audio available through the website for John Hancock College Preparatory High School.)
Sample materials:
Take a sneak peek at the rich instruction and engaging activities for this unit by viewing the PDFs below.
Why we added this unit:
With this domain, students become tomorrow’s problem solvers in this study of energy in the United States. Analytical reading skills are developed by examining the challenges of early energy innovators. Students then read about current energy practices and young energy change-makers across the world.
Throughout the unit, students conduct research into different sources of energy and present a proposal, putting them in the shoes of future energy innovators. They also use the knowledge sequence in this unit to:
- Collaboratively analyze texts to identify cause-effect and problem-solution relationships.
- Generate questions and conduct research about energy.
- Write an opinion essay making their case for a fuel of the future.
- Create energy proposals using primary and secondary resources.
How this unit builds knowledge:
This unit builds upon the following Caminos units that students will have encountered in previous grades as well as earlier in the year.
- Plantas (Grade K)
- La historia de la Tierra (Grade 1)
- ¡Eureka! Estudiante inventor (Grade 4)
The specific core content targeted in these domains is particularly relevant to the Read-Alouds students will hear in Energía: pasado, presente y futuro. The background knowledge students bring to this unit will greatly enhance their understanding of the trade books used in this unit.
Trade books in this unit:
Instruction in this unit revolves around the following collection of high-interest authentic trade books. One copy of each trade book is included with the unit materials.
- La historia de los combustibles fósiles por William B. Rice
- El niño que domó el viento por William Kamkwamba y Bryan Mealer
Sample materials:
Take a sneak peek at the rich instruction and engaging activities for this unit by viewing the PDFs below.
Why we added this unit:
Within this domain, Students learn about General Granger’s announcement in Galveston, Texas on June 19, 1865, a day marked in history as Juneteenth. Texts and multimedia sources will support foundational knowledge-building about the end of slavery in the United States. A review of the first freedom announcement, President Lincoln’s Emancipation Proclamation, provides students with background knowledge to further emphasize the significance of Juneteenth in American history.
This unit also takes students on a journey beyond Juneteenth, as they study specific contributions of African Americans from 1865 to the present day. Students participate in a virtual field trip to Emancipation Park in Houston, Texas and use the knowledge sequence in this unit to:
- Collaboratively generate research questions about Juneteenth, The Great Migration, innovators and inventors, education, the humanities, activists, and allies.
- Use Read-Alouds, independent, and partner reading to learn about African American contributions from 1865 to the present.
- Research to find answers to their generated questions, gather information, and write a four-chapter Beyond Juneteenth book.
How this unit builds knowledge:
This unit builds upon the following Caminos units that students will have encountered in previous grades.
- Los nativos americanos (Grade K)
- Una nueva nación: la independencia de los Estados Unidos (Grade 1)
- La Guerra Civil de los Estaods Unidos (Grade 2)
- La inmigración (Grade 2)
- Los nativos americanos (Grade 5)
The specific core content targeted in these domains is particularly relevant to the Read-Alouds students will hear in Más allá de Juneteenth: de 1865 al presente
. The background knowledge students bring to this unit will greatly enhance their understanding of the trade books used in this unit.
Trade books in this unit:
Instruction in this unit revolves around the following collection of high-interest authentic trade books. One copy of each trade book is included with the unit materials.
- Martí’s Song for Freedom/Martí y sus versos por la libertad escrito por Emma Otheguy
- ¡Celebremos Juneteenth! escrito por Carole Boston Weatherford
- Side by Side/Lado a Lado: The Story of Dolores Huerta and Cesar Chavez/La Historia de Dolores Huerta y César Chávez escrito por Monica Brown
- Canto de alabanza para el día: Poema para la ceremonia inaugural del mandato de Barack Obama escrito por Elizabeth Alexander, traducido por Rodrigo Rojas
Sample materials:
Take a sneak peek at the rich instruction and engaging activities for this unit by viewing the PDFs below.
Wide-ranging texts
Amplify Caminos puts a variety of texts in the hands of students every day.
Amplify Caminos includes both transadaptations and authentic texts written by Latin American and Spanish authors. Our texts feature a wide variety of authors, topics, individuals and characters representing many different socioeconomic statuses, ages, abilities, races, ethnicities, countries of origin, religions, and more.
Amplify Caminos texts include:
- Authentic literature: Authentic literature exposes students to a variety of text types and perspectives to deepen their knowledge of fascinating topics in social studies, science, literature, and the arts. Authentic texts support text-to-self, text-to-world, and text-to-text connections for readers.
- Decodable Student Readers: Decodable Student Readers at grades K–2 are newly redesigned to include students from all walks of life and educational backgrounds. They feature characters with a broad range of backgrounds, experiences, ages, races, religions, and more.
- ReadWorks® texts: Amplify and ReadWorks have partnered to deliver high-quality texts curated to support the Amplify Caminos Knowledge Sequence and to extend student learning. Texts include high-interest nonfiction articles in topics in social studies, science, literature, and the arts. These texts are accompanied by vocabulary supports and standards-aligned formative assessment opportunities. Teachers can monitor their students’ progress using the ReadWorks reporting features.
Amplify Caminos Trade Book Collection Guide
Each book in our authentic literature collection was selected specifically to support and enhance the content of the K-2 Conocimiento Strand. These anchor texts are intended for use as an introduction to each domain—engaging students, piquing their curiosity, and building initial background knowledge—before diving into the deeper content of the domain Read-Alouds.
Every trade book has an instructional guide that includes the following:
- Author and illustrator
- Book summary
- The Essential Question of the Knowledge domain, connecting the book to the domain
- Key Tier 2 and Tier 3 vocabulary words found in the book
- A group activity to reinforce and extend students’ knowledge and understanding
- A performance task to help gauge students’ comprehension of concepts in the text
- Writing prompts to expand understanding and critical thinking
- Text complexity ratings and descriptors for quantitative, qualitative, and reader/task categories
Download the Amplify Caminos Trade Book Collection Guide for Grades K–2.
Detailed information about text complexity ratings and descriptors; additional uses for the books before, during, and after domain instruction; and the complete list of domains and books for each grade level can be found in the More About the Books section of this guide.
What makes Amplify Caminos different?
Built on the Science of Reading
Built out of the latest research in the Science of Reading, Amplify Caminos delivers explicit instruction in both foundational literacy skills (systematic phonics, decoding, and fluency) and background knowledge in grades K–2 with an integrated approach to explicit instruction in grades 3–5.
Explicit systematic skills instruction
The skills instruction in Amplify Caminos was distinctly developed with the Spanish language in mind. Its foundational lessons are specific to the language, rather than a direct translation from Amplify CKLA’s English skills instruction.
Reading instruction begins with the vowels first, then the most common consonants, and finally the least common consonants. Students will blend and segment sounds to form syllables, and syllables to form words.
Although Spanish has a highly predictable orthography, there are a few silent letters (h is always silent, u is silent after g or q), as well as letters that can make different sounds, depending on the letters that follow them. For that reason, syllables with these letters are taught somewhat later in the progression. The same is true for syllables with infrequently occurring consonants, such as z, k, x, and w.
Coherent knowledge instruction
While students are learning how to read, the Conocimiento strand gives them authentic and engaging reasons to read.
Amplify Caminos uses spiral learning to reinforce every student’s ability to develop skills like reading, writing, speaking, and listening in Spanish that can be transferred to English. As students engage with their lessons, they explore the similarities and differences in grammar, vocabulary, writing, and language use between Spanish and English. This bridge helps students learning two languages to strengthen their knowledge in both.
Through cross-curricular content, students explore units that relate to storytelling, science, and the history of our world in a holistic and thoughtful way. With these units, you’ll bring the world to your students, showing them how reading can become an exciting, rewarding, and useful part of their lives.
Embedded differentiation for all learners
Amplify Caminos provides built-in differentiation strategies and supports in every lesson.
- Apoyo a la enseñanza y desafío: Support and Challenge suggestions in every lesson provide assistance or opportunities for more advanced work toward the goal of the lesson.
- Notas culturales: These point-of-use notes provide additional information about the traditions, foods, holidays, word variations, and more from across the Spanish-speaking world.
- Apoyo adicional: Every lesson in the Lectoescritura (Skills) Strand provides additional support activities suggested to reinforce foundational skills instruction. These activities can be given to any student who requires extra help, including students with special needs.
Systematic and cohesive writing instruction
Writing instruction in Amplify Caminos builds systematically and cohesively within and across grades.
In Grades K-2, writing mechanics—including handwriting and spelling—are taught in the Amplify Caminos Lectoescritura strand. Starting in Grade 1, instruction includes four steps in the writing process: planning, drafting, editing, and publishing and features lessons that have modeling, collaboration, and sharing. As students gain skills and confidence, they are able to take on more of these steps independently. Students learn to use planning techniques, including brainstorming and graphic organizers.
Beginning in Grade 4, the Amplify Caminos writing process expands to also include sharing and evaluating. In Grades 4 and 5, the writing process is no longer conceptualized as a series of scaffolded, linear steps (an important change from the Grade 3 writing process). Rather, students move between components of the writing process in a flexible manner, similar to the process mature and experienced writers follow naturally.
Amplify Caminos’ writing instruction provides a clear progression through the text types in each grade.
Because Amplify Caminos has two strands of lessons in Grades K-2, Lectoescritura and Conocimiento, students are exposed to both narrative and informational texts throughout the year. In Grades 3-5, the integrated units feature study in literary, informational, or a mix of both types of texts, depending on the content of the unit.
- Grades K–2 introduce and establish the key elements of each text type, allowing students to gain comfort and confidence writing narratives, opinions, and informative texts. This enables students to practice thinking about content in different ways, offering more depth and breadth to their understanding of core content and of the writing text types.
- By Grade 3, students will have gained significant practice in narrative, opinion/argumentative, and informational/explanatory forms of writing and will continue to apply those skills through Grade 5.
How does Amplify Caminos integrate with the other parts of the literacy system?
Amplify Caminos + mCLASS® Lectura
Achieve complete parity between English and Spanish assessments with mCLASS Lectura for K–6. mCLASS Lectura allows teachers to connect with their Spanish-speaking students face-to-face, one-on-one, and in the language most comfortable to them. The result? Valid and reliable student data reports
available in both English and Spanish, enabling teachers to pinpoint where their Spanish-speaking or emergent bilingual students really are in their skill development and what instruction to prioritize.
Amplify Caminos + Amplify Reading
Amplify Reading is an engaging, adaptive digital program that extends the learning in Amplify Caminos. Amplify Reading offers support to a large sub-group of English learners (ELs) through Spanish voice-over. Spanish voiceover instructions are available in vocabulary and sentence-level comprehension games so ELs can build their vocabulary, language, and critical comprehension skills before moving into analyzing complex texts
Demo access and sample materials
Ready to explore on your own? First, watch the videos below to learn about the program’s components and how to navigate the digital platform.
Physical materials walkthrough video
Digital navigation video
Demo access
Next, follow the instructions below to access your demo account.
- Click the CKLA and Caminos Demo button below.
- Select Log in with Amplify.
- To explore as a teacher, enter this username: t1.sfusdreviewer@demo.tryamplify.net
- To explore as a student, enter this username: s1.sfusdreviewer@demo.tryamplify.net
- Enter the password: Amplify1-sfusdreviewer
- Click the Programs and apps menu
- Select CKLA Teacher Resource Site
- Select the desire grade level
- Use the toggle to switch between English (CKLA) and Spanish (Caminos) resources.
Sample materials
Finally, click on the grade levels below to explore your requested sample units.
Conocimiento Strand:
- Guía del maestro, Conocimiento 12: Luchar por una causa
- Cuaderno de actividades, Conocimientos 7–12
- Rotafolio de imágenes, Conocimiento 12
- Tarjetas de imágenes, Conocimiento 12
Lectoescritura Strand:
Additional resources
- Caminos Program Guide
- Biliteracy and Science of Reading Principles
- Amplify Caminos Conocimiento Scopes and Sequences
- Grade K Knowledge Strand
- Grade 1 Knowledge Strand
- Grade 2 Knowledge Strand
- Grade 3 Integrated Strand
- Grade 4 Integrated Strand
- Grade 5 Intgrated Strand
S3 – 04. Ideas to build math fluency with Valerie Henry, Graham Fletcher, and Tracy Zager
Fluency in math can oftentimes be associated with negative experiences with its development— timed worksheets, for example. Bethany and Dan are joined by three guests to better understand fluency and how to make its approach fun. Dr. Val Henry shares her three-part definition of fluency and her five principles for developing it. Additionally, Tracy Zager and Graham Fletcher join Bethany and Dan to better understand fluency through a lens of equity and using multimedia as a tool.
Explore more from Math Teacher Lounge by visiting our main page.
Dan Meyer (00:03)
Hey folks. Welcome back. This is Math Teacher Lounge, and I am one of your hosts, Dan Meyer.
Bethany Lockhart Johnson (00:07):
And I’m your other host, Bethany Lockhart Johnson. Hi, Dan.
Dan Meyer (00:11):
Hey, great to see you. We have a big one this week to chat about and some fantastic guests. We are chatting about fluency, which is the sort of word and concept that I feel like people have very, very non-neutral associations with it. A lot of them are very negative, for a lot of people.
Bethany Lockhart Johnson (00:26):
I saw you frown a little. What’s up with that, Dan? You kind of, like, shrank.
Dan Meyer (00:30):
I have strong feelings about it. You know, there’s lots of ways that people go about helping people become fluent in mathematics. And a lot of them are harmful for students, and ineffective. And it got me thinking about fluency as it exists outside of the world of mathematics, where we have a lot of very clear images of it. We’re getting fluent in things all the time. Like, as humans. Human development is the story of fluency. And I just was wondering….Bethany, would you describe yourself as fluent at something outside of the world of mathematics? What is that? How’d you get fluent at it? What was the process?
Bethany Lockhart Johnson (01:05):
Hmm, I think I’m a pretty fluent reader. I read all the time. I’m a happier person if I’ve read that day. I once saw this poster in a classroom; it said “10 Ways to Become a Better Reader: Read, Read, Read, Read, Read…you know, 10 times. Get it? Reading? You get better at reading by reading! So I would say reading. And it’s been kind of cool—I have a one-year-old who, it’s been really exciting slash overwhelmingly anxiety-producing to see him get very fluent with walking slash running, ’cause he’s getting faster every day. And it’s kind of fun. When I think of what’s something somebody’s trying to get fluent with…walking! He’s trying to be more fluid. He’s practicing transitions. He doesn’t wanna hold my hand while he traverses rocky terrain. He’s getting better at it. He’s practicing. What about you? What’s something…?
Dan Meyer (02:08):
I think about driving a lot. I’m a very fluent driver and I think a lot about when I was first a driver, you know? And how l have my hands on 10 and 2, vice grip, and do not talk to me; do not ask me anything; don’t ask me my NAME. I need to focus so hard. And then a year later, you know, I’m driving with one hand, smash the turn signal, take a sip off of whatever, change the CD. And then it’s no big deal.
Bethany Lockhart Johnson (02:38):
Wait, did you pass the first time? Your test?
Dan Meyer (02:40):
Yeah, I don’t like to brag about it. <laugh> But I do all the time. <laugh> But I got a hundred on my driving test. I don’t care who knows it. And I hope it’s everybody. But I guess all of this is just to say there are areas of life where fluency feels natural, with the case of walking. There’s areas of life where fluency feels motivating, with like driving—I wanna be able to switch the CD out or whatever. And there’s areas where fluency feels terrifying and hard to come by, like mathematics, sometimes. So we have a set of guests here. Our first guest will help us figure out what do we mean by fluency? And what’s the research say about what fluency is and how students develop it in mathematics? And then our other guests will help us think about what it looks like in practice in the classroom. What are some novel, new ways to work on fluency? So first up we have Val Henry, Dr. Val Henry.
Bethany Lockhart Johnson (03:32):
So we knew we needed help with the fluency definition, because when we think about it, it’s kind of big, right? And we wanted to look at what research about fluency really says. So we called on Valerie Henry. Val is a nationally board-certified teacher, taught middle school for 17 years, and since 2002 has worked with undergraduates graduates, credential candidates as a lecturer at the University of California, Irvine, one of my alma maters. So after doing her dissertation on addition and subtraction fluency in first grade, Val created a project to study ways to build addition and subtraction and multiplication and division fluency while also developing number sense in algebraic thinking. And the pilot grew and grew over the last 18 years into a powerful daily mini-lesson approach to facts fluency called FactsWise. And when we thought of fluency, the first person I thought of was Val. Welcome, Val Henry, to the Lounge! I’m so excited to have you here. Welcome.
Valerie Henry (04:36):
Thanks, Bethany. And thanks to you, Dan. It’s great to be here today.
Dan Meyer (04:41):
Great to have you; help yourself to whatever you find in the fridge. The names that people write down on those things in the bags are just recommendations. It’s potluck-style here. I’m curious, Val, if you’re, like, on an airplane, someone asks you what you do, and you say you study fluency…what is the layperson’s definition of what does it mean to be fluent in mathematics? And if you can give a brief tour through what the research says about what works and what doesn’t that would really help us orient our conversation here.
Valerie Henry (05:12):
The first thing I have to do when I talk to somebody on a plane is define the idea of fluency. And I often use an example of tying your shoelaces. Because that works with first graders as well as adults. This idea that when we first start trying to put our shoes on and get those shoelaces tied, somebody tries to, first of all, just do it for us. But then of course maybe tries to teach us the bunny-ears approach. And we struggle and struggle as little kids and eventually either the bunny-ears approach or something else starts to work for us. But we still have to pay attention to it. We have to think hard and it’s not easy. And then over time we get to the point where we basically don’t even think about it. When I tie my shoes in the morning. I’m not thinking about right-over-left and left-over-right and all of those things. I just do it. And so that’s a good, easy example of becoming fluent with something. I think what we’re talking about today though, is the basics, the adding and subtracting that we hope kids are going to have mastered maybe by second grade, and the multiplication and division facts that we wanna maybe have mastered by third, maybe fourth grade. So now what does that mean to become fluent with those basics? I have a three-part definition that seems to match up really nicely with the common core approach to fluency. Which is, first of all, we want the answers to be correct. And then second, we want the answers to be easy to know. And so what does that mean? Well, to me, it means without needing to count,
Bethany Lockhart Johnson (07:12):
You mean without having to kind of muscle through it? Or say more about you mean.
Valerie Henry (07:16):
Well, I guess what I mean is that when you watch a young child try and solve something even as simple as two plus three, they might put up two fingers and then go 3, 4, 5 with three more fingers winding up on their hand, one or the other of their hands. While they’re doing that, they don’t really have a sense of whether even their answer is right or not, quite often. Especially when you get to the larger adding and subtracting problems, you can see a lot of errors happening as they’re trying to count. And it’s taking up cognitive energy to do that counting process, especially as you get to the larger quantities. So my definition of fluency now is “getting it right without needing to do that hard work like counting.” Now, some people might say, well, we just want them to have ’em memorized. But in my research, I’ve learned that a lot of very fluid adults don’t always have every fact memorized. In fact, if you ask a room full of adults, what’s seven plus nine, you might learn that they can all get it correct quickly, quickly…but they don’t all have it memorized. And so when you ask them, “How did you get that?” Many of them will say, “Well, I just gave one from the 7 to the 9 and I know that 10 plus 6 is 16.”
Bethany Lockhart Johnson (08:53):
That’s such an important distinction. My brain literally just did that actually!
Valerie Henry (08:58):
<laugh> Right? <laugh> But you’re fluid with it, because it doesn’t take you much cognitive energy at all.
Bethany Lockhart Johnson (09:05):
Right.
Valerie Henry (09:07):
So now we have “correct without needing to put that cognitive energy,” which usually means that you’re counting. And then the third thing is “relatively quickly,” so that you’re not spending 15 seconds trying to figure it out. Even that part-whole strategy approach can be done really quickly, almost instantaneously. Or it can take a long time. So if a student can get the answer correct within, you know, three or four seconds— is I’m pretty generous—I figure that they’re pretty darn fluent with that fact. So that’s my three-part definition of these basics, fluency.
Dan Meyer (09:55):
I love the distinction between getting it correct and getting it quick. It’s possible to be quick with wrong answers. It’s possible to be like, “Those are separate components there.” And I echo Bethany’s appreciation for this third option in between knowing it instantaneously through memorization and muscling through it. But there’s like a continuum there of how much energy it took you to come up with it that all feels extremely helpful.
Valerie Henry (10:21):
And you know, one of the things that I’ve noticed is that when kids are pressured to come up with those instantaneous answers, they often default to guessing and get it wrong.
Bethany Lockhart Johnson (10:30):
Mm, yeah.
Valerie Henry (10:30):
So that’s one of the things that I’ve learned is that as we’re trying to help students develop fluency, it’s important to start with building their conceptual understanding of what it means to do, you know, 3 times 9 and what the correct answer is, maybe using manipulatives or representations of some sort. Not skip-counting! I really have found that skip-counting just perpetuates itself in many students’ minds and that they never stop skip-counting, which means they’re putting in not very much mental energy if it’s 2 times 3 but a ton of mental energy if it’s 7 times 8. Because frankly, it’s really hard to skip count by sevens. And by eights.
Bethany Lockhart Johnson (11:18):
I can get to 14 and then I’m like, wait, wait, what was next? Right? No, no, no…21! What do you feel are some misconceptions that maybe teachers, maybe parents have about fluency in math?
Valerie Henry (11:30):
I think maybe one of the first ones is that if students count or skip-count, their answers repetitively over and over and over and over, that they’re bound to memorize them. And the study that I did back in 2004, I actually had a school that had decided that they were going to do time tests with their students every day, all year. And that undoubtedly by the end of the year, those students would be fluent.
Bethany Lockhart Johnson (12:06):
And to clarify by time test, you mean like, sit down, pencil, paper, ready, go, worksheet kind of thing.
Valerie Henry (12:15):
Yes.
Bethany Lockhart Johnson (12:16):
Some of us might remember quite vividly.
Valerie Henry (12:18):
<laugh> Very vividly. And you know, you have to get it done within a certain amount of time. So they made it fun for the students. Apparently the students enjoyed it. I was a little leery about that, but in the end, when I went and checked on the students and I did one-on-one assessments with half of the students in every class that were randomly selected so that I could get a sense of where they were with their fluency—and these were first graders—they basically had nothing memorized. They were simply counting as fast as they possibly could. And, you know, mostly getting the right answers. But they had not memorized. So that’s one of the myths, I think, is that repetitive practice of counting gets you to memorization.
Bethany Lockhart Johnson (13:10):
If I put it in front of you enough times, you’ll become fluent.
Valerie Henry (13:14):
Right, right. Now these students didn’t really get any instruction, any help learning these. They just simply tested over and over and over. So that’s another thing that I think is a misconception. It’s that if we test students, but don’t really teach them fluency, then they’re going to become fluent. If we just test them every Friday or that kind of thing. And that they’ll learn them at home. But really what that means is a few lucky kids who have parents who have the time and the energy and the background to know how to help will take that job on at home. Not that many students are really that fortunate.
Dan Meyer (14:01):
It’s almost like the traditional approach, or the approach you’re describing, confuses process and product. It says, “Well, the product is that eventually fluent students will be able to do something like this, see these problems and answer them, answer them quickly,” and says, “Well, that must be the process then as well; let’s give them that products a whole lot.” But as I hear you describe fluency with bunny ears on shoelaces, there’s these images and approaches and techniques that require a very active teacher presence to support the development of it. That’s just kind of interesting to me.
Valerie Henry (14:35):
My initial project, the pilot project that I tried, was to simply ask teachers to follow five key principles. And the first one was to do something in the classroom every day for—I told them, even if you’ve only got five or 10 minutes, work on fluency for five or 10 minutes a day, and let’s see what happens. So that was one key element was just to teach it and to give students opportunities to get what the research calls for when you’re trying to memorize, which is actually immediate feedback. When I talk about immediate feedback with my student teachers, I say, “I’m talking about within one or two seconds of trying a problem, and then sort of immediately knowing, getting feedback of whether you got the answer right or not so that your brain can kind of gain that confidence. ‘Oh, not only did I come up with an answer, but somebody’s telling me it’s the correct answer.’”
Dan Meyer (15:38):
There’s a lot of apps now in the digital world that offer students questions about arithmetic or other kinds of mathematical concepts and give immediate feedback of a sort: the feedback of “You’re right; you’re wrong” sort. Is that effective fluency development, in your view?
Valerie Henry (15:57):
I haven’t heard and I haven’t seen them being super-effective. The ways I think about this are “Immediate feedback isn’t the only thing we need.” Probably one of the biggest things that we need is for students to develop strategies. And this is one of the other things I’ve learned from international research, from countries that do have students who become very fluent very early, is that they don’t shoot straight for memorization, but they go through this process of taking students from doing some counting and then quickly moving them to trying to use logic. So, “Hey, you really are confident that 2 + 2 is 4; so now let’s use that to think about 2 + 3.” Actually, as an algebra teacher, I would much rather have students that have a combination of memorization and these strategies, than students who’ve only memorized. Isn’t that interesting that my most successful algebra students were good strategy thinkers. Not just good memorizers.
Bethany Lockhart Johnson (17:09):
So you mentioned there were five that kind of helped root this idea in like, “What can teachers do? What is the best thing that teachers can do to support with fact fluency?” So, everyday was key.
Valerie Henry (17:22):
Then the next principle that I really focus on is switching immediately to the connected subtractions so that students—
Bethany Lockhart Johnson (17:33):
Not waiting until you’ve gotten all the way through addition. But making “Ooh!”
Valerie Henry (17:38):
Totally. And I didn’t do that the first year. And when we looked at the results of the assessments at the end of the year, we realized that our students were so much weaker in subtraction than addition. So the following pilot year, we tried this other approach of doing subtraction right after the students had developed some fluency with that small chunk of addition. And we got such better subtraction results.
Bethany Lockhart Johnson (18:11):
What are the other principles?
Valerie Henry (18:13):
The biggest one is to use these strategies. So the strategies makes the third. And then the fourth I would say is to go from concrete to representational to abstract.
Bethany Lockhart Johnson (18:27):
Don’t put away those manipulatives. Don’t put away those tools.
Valerie Henry (18:31):
Oh, so important to come back to them for multiplication and division. And my fifth principle is to wait on assessment. To use it as true assessment, but not race to start testing before students have had a chance to go through this three-phase process. Which is conceptual understanding with manipulatives; building strategies, usually with representations; and then working on building some speed until it’s just that natural fluency.
Bethany Lockhart Johnson (19:07):
I wanna say thank you so much for offering your really learned perspective, because you have not only done the research, but seen it in action and seen how shifting our notions of fluency and what fluency can be and what a powerful foundation it can be for all mathematicians. Really, that shift is so powerful. And I appreciate you sharing it with our listeners and with us. So we’re so excited that we got to talk with you today, Val—
Dan Meyer (19:35):
Thank you, Dr. Henry.
Valerie Henry (19:37):
You’re welcome!
Dan Meyer (19:41):
With us now we have Graham Fletcher and Tracy Zager, a couple of people who understand fluency at a very deep and classroom level. I wanna introduce them and get their perspective on what we’re trying to solve here with fluency. So Graham Fletcher has served in education in a lot of different roles: as a classroom teacher, math coach, math specialist, and he’s continually seeking new and innovative ways to support students and teachers in their development of conceptual understanding in elementary math. He’s the author, along with Tracy, of Building Fact Fluency, a fluency kit we’ll talk about, and openly shares so much of his wisdom and resources at gfletchy.com. Tracy Johnson Zager is a district math coach who loves to get teachers hooked on listening to kids’ mathematical ideas. She is a co-author of this toolkit, Building Fact Fluency, and the author of Becoming the Math Teacher You Wish You’d Had: Ideas and Strategies from Vibrant Classrooms. Tracy also edits professional books for teachers at Stenhouse Publishers, including, yours truly. Thank you for all that insight, Tracy, and support on the book.
Bethany Lockhart Johnson (20:49):
Dan and I were talking at the beginning of the episode about things we feel like, “Hey, I’m fluent in that. I’m fluent in that.”
Dan Meyer (20:55):
Just very curious: What’s something you would like to get fluent in outside of the world of mathematics, let’s say?
Tracy Zager (21:00):
I’ll say understanding the teenage brain, as the parent of a 13-year-old and 15-year-old. That’s the main thing I’m working on becoming fluent in!
Bethany Lockhart Johnson (21:10):
Ooh!
Dan Meyer (21:13):
A language fluency, perhaps. All right, Graham. How about you?
Graham Fletcher (21:16):
For me typing, it’s always been an Achilles heel of mine. So voice-to-text has been my friend. But it’s also been my nemesis in much of my texting here and working virtually over the last couple years. So yeah, typing.
Dan Meyer (21:33):
Do you folks have some way of helping us understand the difference in how fluency is handled by instructors and by learners?
Tracy Zager (21:40):
I would say that the lay meaning of fluency is definitely a little different than what we mean in the math education realm. When we’re talking about math fact fluency, which is just one type of fluency. So you gotta think about procedural fluency and computational fluency; there are lots of types of fluency in math. And Graham and I had the luxury of really focusing in specifically on math fact fluency. We’re looking at kind of a subset of the procedural fluency. So the words you hear in all the citations are accurate, efficient, and flexible. There’s this combination of kids get the right answer in a reasonable amount of time and with a reasonable amount of work and they can match their strategy or their approach to the situation. That’s where that flexibility comes in. And there’s like lots more I wanna say about that about sort of…I think one issue that comes up around fluency is that people are in a little bit of a rush. So they tend to think of the fluency as this automaticity or recall of known facts without having to think about it. And that is part of the end goal, but that’s not the journey to fluency. So this is one of the things that Graham and I thought about a lot was the path to fluency. The goal here it’s that student in middle school who’s learning something new doesn’t have to expend any effort to gather that fact. And they might do it because they’ve done it so many different ways that they’ve got it, and now they just know it, or they might be like my friend who’s a mathematician who still, if you say, “Six times 8,” she thinks in her head, “Twelve, 24, 48…” and she does this double-double-double associative property strategy. And it’s so efficient, you would never know. And that’s totally great. That’s fine. That’s not slowing her down. That’s not providing a drag in the middle of a more complex problem or new learning. So we’re really focused on having elementary school students be able to enter the middle and high school standards without having that pull out of the new thinking.
Graham Fletcher (23:53):
And as I think about that, I think about how so many students will memorize their facts, but then they haven’t memorized them with understanding. So that when they move into middle school and they move into high school, it’s almost like new knowledge and new understanding that’s applied from a stand-alone skill.
Bethany Lockhart Johnson (24:10):
So something that felt really unique to me, Graham, as I was diving into the toolkit, is your use of images, Tracy, Graham, is the way that you use images to help students notice and wonder to start making sense of these quantities and the decomposition of numbers using images. Can you talk a little bit about how images played a part in the way that you think about this building a fact fluency?
Graham Fletcher (24:41):
What I realized is so many times when we approach math with just naked numbers with so many of our elementary students, the numbers aren’t visible. The quantities. They can’t see them; they can’t move them. They’re just those squiggly figures that we were talking about earlier on. So how is it that we make the quantities visible, to where students feel as if they can grab an apple and move it around? Because a lot of times we start with the naked numbers and then if kids don’t get the naked numbers, then we kind of backfill it. But what would happen if we start with the images? And then from there, these rich, flourishing mathematical conversations develop from the images. And I think that was the premise and the goal of the toolkit.
Tracy Zager (25:22):
When you look at how fact fluency has traditionally been taught, it’s all naked numbers. And sometimes we wrote ’em sideways. Like, that’s it. That was our variety of task type. Right? Sometimes it’s vertical; sometimes it’s horizontal. And that was it. And I’ve just known way too many kids who couldn’t find a hook to hang their hat on with that. It didn’t connect to anything. And so part of why I knew Graham was the perfect person for this project was his strength in multimedia photography, art, video. And so we started from this idea of contexts that for each lesson string in the toolkit, there’s some kind of context. An everyday object, arranged in some kind of a way that reveals mathematical structure and invites students to notice the properties. So we start with images of everyday objects: tennis balls, paint pots…um, help me out; here are a million of them. Crayons—
Bethany Lockhart Johnson (26:18):
Crayons, markers.
Tracy Zager (26:18):
Shoes, right? Sushi, origami paper, all kinds of things in the different toolkits. So there’s a series of images or a three-act task or both around those everyday objects, and then story problems grounded in that context. And then there are images with mathematical tools that bring out different ideas, but relate in some way to the image talks. And we do all of that before we get to the naked number talk. Which we do, and by the time you get to the number talk, it’s pretty quick, ’cause they’ve been reasoning about cups of lemonade. And now when you give them the actual numerals, they’re all over it.
Bethany Lockhart Johnson (27:03):
I have to say too, as somebody who—particularly in middle school—navigated math anxiety, we recently talked with Allison Hintz and Anthony Smith about their amazing book Mathematizing Children’s Literature.
Tracy Zager (27:14):
Yay!
Bethany Lockhart Johnson (27:14):
And I was explaining, like, if I sat down at the beginning of a math class and my teacher opened a picture book and said, “We’re gonna start here,” I felt my whole body relax. And if we start with this image, if we start with just looking at an image and making sense of an image, I feel like that could be such a powerful touchstone for all the work you do from there.
Tracy Zager (27:41):
That’s core. That’s a core design principle, is that invitational access. There are no barriers to entry. There’s nothing to decode. There’s nothing formal. We’ve been learning from Dan for years about this, right? Of starting with the informal and then eventually layering in the formal. I was in a class in Maine where they were doing an image talk and it’s these boxes of pencils. It’s a stack of boxes of pencils and they’re open and you can see there are 10 pencils in each box. And so there are five boxes of pencils each with 10 pencils in it. And then the next image is 10 boxes of pencils and each box is half full. So now it’s 10 boxes each with five. And the kids are talking and talking and then the third image, I think there are seven boxes each with 10 pencils in it. And she said, “What do you think the next picture’s gonna be?” And this girl said, “You just never know with these people!” <laugh> I dunno!”
Bethany Lockhart Johnson (28:37):
That’s kinda true. Knowing you both, it’s kinda true.
Tracy Zager (28:42):
Like if it’s seven boxes with 10 in it, one kid said, I think it’s gonna be 14 boxes of five. And other kids are like, I think it’s gonna be 10 boxes with seven. And they start talking about which of those there are and the relationships between—
Bethany Lockhart Johnson (28:58):
But they’re making sense of numbers!
Tracy Zager (28:59):
Totally. So all the kids felt invited. They can offer something up. They’re noticing and wondering about that image. They’re talking about it in whatever informal language or home language that they speak. And that was core to us. That was a huge priority, because honestly, one of the motivations to talk about fluency is that it’s always been this gatekeeper. It has served to keep kids out of meaningful math. Particularly kids from marginalized or historically excluded communities. So they’re back at the round table, doing Mad Minutes, while the more advantaged kids are getting to do rich problem solving. And so, we thought, what if we could teach fact fluency through rich problem solving that everybody could access? That was like square one for us.
Bethany Lockhart Johnson (29:45):
That’s huge.
Dan Meyer (29:46):
That’s great to hear. What’s been helpful for me is to understand that students who are automatic, that’s just kind of what’s on the surface of things. And that below that might be some really robust kind of foundation or scaffolding that bleeds to a larger building being built, or it might be just really rickety and not offer a sturdy place to build farther up. It’s been really exciting to hear that. I wonder if you’d comment for a moment about, in the digital age and—I’m at Desmos and our sponsors are Amplify and we all work in the digital world quite a bit. There are a lot of what report to be solutions to the fluency issue, to developing fluency in the digital world. Just lots and lots of them. Some that are quite well used, others that are just like X, Y, or Z app on the market. You can find something. Do you have perspectives on these kinds of digital fluency building apps? Like, what about them works or doesn’t work? Let us know. Graham, how about you? And then Tracy, I’d love to hear your thoughts too.
Graham Fletcher (30:47):
Yeah, I think that’s a great question, ’cause there’s a lot of shiny bells and whistles out there right now that can really excite a lot of teachers. But I always come back to what works for me as a classroom teacher is probably gonna work in a digital world as well. So what are the things that I love and honor most about being in front of students, and how can I capture that in that virtual world? I think one of the things that really helps students make connections is coherence. I think coherence, especially when you leave students for—you don’t get to talk with them after the lesson is done—so I think about how we can purposefully sequence things through a day-to-day basis. I think coherence is something that gets really lost when we talk about fluency, especially with whether it be digital or whether it be print, because what ends up happening is we say, “OK, we have all these strategies we need to teach,” and it becomes a checklist. So how is it that we can just provide students the opportunity to play around in a space, whether it be digital or in person, but in a meaningful way that allows them the time and the space and that area to breathe and think, but be coherent. And connecting those lessons along the way. And I think coherence is one thing that a lot of the times it’s harder to—when we’re in the weeds, it’s so hard and difficult to zoom back out and say, “Do all these lessons connect? How do they intentionally connect? And how do they purposefully connect?” And without coherence, everything’s kind of broken down into that granular level. So when looking at—I think about Desmos and I think about the Toolkit and I think about how Tracy and I talked a lot about, “Well, this, does it connect with the context problem, does it connect with the image talk, or the lessons? Like, how does it all connect and how are we providing students an opportunity to make connections between the day-to-day instruction and lessons that we tackle?”
Tracy Zager (32:44):
I’m reminded of a conversation that Dan, you and I had a long time ago, in Portland, Maine, in a bar. I’ll just be honest. <laugh> And we were talking about how, in the earlier days of Desmos, you were stressed out by what you saw, which was kids one-on-one, on a device, in a silent room. And you were like, no, this is not it. This is not what technology is here to serve. We can do so many things better using technology appropriately, but we can’t lose talk and we can’t lose relationships and we can’t lose formative assessment and teachers listening to kids and kids listening to each other and helping each other understand their thinking. Right? So when I think about the tech that’s out there for fact fluency, most of it is gonna violate all rules I have around time testing. So that a whole bunch of it, I would just toss on that premise. They’re really no different than flashcards. It’s just flashcards set in junkyard heaps. Or, you know, underground caverns. Or with a volcano or whatever. It’s the same thing. There are some lovely visuals—I’m thinking of Berkeley Everett’s Math Flips. Those are really pretty. Mathigon has some really nice stuff that’s digital. And I think that those resources invite you to kind of ponder and notice things and talk about them. All the tools that we design in the toolkit are designed to get people talking to each other, and give teachers opportunities to pull alongside kids and listen in and understand where they are. For example, our games, we didn’t design the games to be played digitally, even though you could, and people did during COVID, because we want kids on the rug, next to each other, on their knees; I’ve seen kids like across tables. I was in a school recently where a kid was like, “I hope you believe in God, ’cause you’re going…!” You know what I mean? <laugh>. Like they’re all pumped up.
Bethany Lockhart Johnson (34:41):
They’re invested!
Tracy Zager (34:45):
They’re psyching each other up and down and they’re interacting and it’s social and the teacher’s walking around and she’s listening to the games. And they don’t actually need any bells and whistles. They need dice and they need counters and they need this game that is actually a game. In all of our conversations, games have to actually be games. Games cannot be “roll and record.” Games have to involve strategy. They have to be fun. So in designing those games, we didn’t feel like it brought any advantage to make that a digital platform. But things that did bring advantages digitally, like the ability to project these beautiful images or to use short video in the classroom, that really was a value-add that enabled us to do something different in math class than we had done before, and to get kids talking in a different way than they ever had before. When I think about fluency, historically, if you say like, “OK, it’s time to practice our math facts,” you hear a lot of groans. And when I see a Building Fact Fluency classroom and I say, “OK, it’s BFF time!” There’s like a “YEAAAAHHH!” You know? And so that’s what we’re after.
Graham Fletcher (35:47):
It’s all about kids, really, for us. And I think at the heart of it, we made all the decisions with teachers and kids at the forefront of it.
Tracy Zager (35:55):
I know of high schoolers who are newcomers, who have experienced very little formal education, and speak in other languages, are using it as high schoolers, because it involves language and math and all the deep work in the properties and it’s accessible, but it’s also not at all condescending or patronizing. Like we designed it to be appropriate for older kids. So that’s just something that I think we’re both really proud of. One thing we thought a lot about, especially in the multiplication-division kit is how a classroom teacher could use it and a coordinating educator in EL, Title, special education, intervention could also use it because there’s so much in it, that students could get to be experts, if they got extra time in it, using something that’s related and would give them additional practice. So they could play a game a little bit earlier than the rest of the classes. And they could come in already knowing about that game, or they could do a related task. We have all these optional tasks that no classroom teacher would ever have time to teach it all. So the special educator could use it and have kids doing a Same and Different or a True/False, or some of the optional games. And then the work in both special education and general education could connect.
Dan Meyer (37:20):
I just wanna say that this is an area that for so many students, as you’ve said, Tracy, it presents a barrier for their inclusion in mathematics. It’s a very emotionally fraught area of mathematics. And we really appreciate the wisdom you brought here. And just the care you’ve brought to the product itself. Your knowledge of teaching, knowledge of math, and yeah, especially a love for students feels like it’s really infused throughout Building Fact Fluency. If our listeners want to know more outside of this podcast, outside of the product itself, where can they find your words, your voice? Where you folks at these days? Tell ’em, Graham would you?
Graham Fletcher (37:57):
You can find us at Stenhouse, Building Fact Fluency. And then Tracy and I, currently playing around, sharing ideas a lot on Twitter, under the hashtag #BuildingFactFluency. That’s kind of where we can all come together and share ideas. And then also on the Facebook community, where there’s lots of teachers sharing ideas.
Bethany Lockhart Johnson (38:19):
If you were to ask our listeners like, “Hey, if you wanna keep thinking about this, here’s something you could try or here’s something you could go do,” what could be a challenge that we could share that could help us continue this conversation?
Graham Fletcher (38:35):
Online you can actually download a full lesson string. And a lesson string is a series of activities and resources that are purposefully connected. You can pick one or two of those from the Stenhouse web site, Building Fact Fluency. You can try the game. You can try one of those strategy-based games. You can try an image talk and just see how it goes. And just share and reflect back, whether on Twitter or on Facebook. But it’s kind of there, if you wanna give it a whirl. And as Tracy was sharing, even if you’re a middle-school teacher or a high-school teacher, we really tried to think about those middle-school and high-school students keeping it grade level-agnostic. Just so every student has those opportunities for those mathematical conversations. So download a lesson string and give it a whirl, and we’d love to hear how it goes.
Dan Meyer (39:25):
Bethany and I will be working the same challenge with people in our life.
Bethany Lockhart Johnson (39:29):
Yes.
Dan Meyer (39:29):
Enjoying some fact fluency with people in our homes, perhaps. We’ll see. And we’ll be sharing the results in the Math Teacher Lounge Facebook group. Graham and Tracy, thanks so much for being here. It was such a treat to chat with you both.
Bethany Lockhart Johnson (39:42):
I love learning with you and just helping to shift this idea of fluency into something that can be accessible and powerful and positive.
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Meet the guests
Valerie Henry has been a math educator since 1986. She taught middle school math for 17 years and has worked as a lecturer at University of California Irvine since 2002. After doing her 2004 dissertation research on addition/subtraction fluency in first grade, Valerie created FactsWise, a daily mini-lesson approach that simultaneously develops fluency, number sense, and algebraic thinking. Additionally, she has provided curriculum and math professional development for K-12 teachers throughout her career, working with individual schools, districts, county offices of education, Illustrative Mathematics, the SBAC Digital Library, and the UCI Math Project.
Graham Fletcher has served in education as a classroom teacher, a math coach, and currently as a math specialist. He is continually seeking new and innovative ways to support students and teachers in their development of conceptual understanding in elementary mathematics. He is the author of Building Fact Fluency and openly shares many of his resources at gfletchy.com. Follow him on Twitter.
Tracy Johnston Zager is a district math coach who loves to get teachers hooked on listening to kids’ mathematical ideas. She is a co-author of the Building Fact Fluency toolkits and the author of Becoming the Math Teacher You Wish You’d Had: Ideas and Strategies from Vibrant Classrooms. Tracy also edits professional books by teachers, for teachers at Stenhouse Publishers. Follow her on Facebook.
About Math Teacher Lounge: The podcast
Math Teacher Lounge is a biweekly podcast created specifically for K–12 math educators. In each episode co-hosts Bethany Lockhart Johnson (@lockhartedu) and Dan Meyer (@ddmeyer) chat with guests, taking a deep dive into the math and educational topics you care about.
Join the Math Teacher Lounge Facebook group to continue the conversation, view exclusive content, interact with fellow educators, participate in giveaways, and more!
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Amplify Desmos Math California incorporates the Drivers of Investigation (DIs) and Content Connection (CCs) throughout the program. Throughout the year, students engage with open and authentic tasks of varying durations — from lesson activities to unit-level Explore lessons and longer course-level Investigations. Every lesson and investigation opportunity is grounded around the why, how, and what of the learning experience, and helps teachers bring mathematical concepts to life.
California English Language Development Standards
Linked here is the alignment of Amplify Desmos Math California to the California English Language Development Standards for Math 1.
California Environmental Principles and Concepts
Select lessons, performance tasks, and investigations across grade levels in Amplify Desmos Math California are aligned to one or more of the California Environmental Principles and Concepts. Click this link to view how the California Environmental Principles and Concepts are represented in Amplify Desmos Math California Math 1.
Category 2: Program Organization
Amplify Desmos Math California thoughtfully combines conceptual understanding, procedural fluency, and application. Each lesson is designed to tell a story by posing problems that invite a variety of approaches before guiding students to synthesize their understanding of the learning goals.
Big Ideas
Amplify Desmos Math California’s courses, units, and lessons are centered around the Big Ideas. Big Ideas, like standards, are not considered in isolation. In addition to each unit and lesson’s focal Big Ideas, Amplify Desmos Math California also provides connections among the Big Ideas across units and lessons. Please refer to Keeping the Big Ideas at the Center, linked here, for the Amplify Desmos Math California Math 1 lesson design and alignment to the Big Ideas.
Program Structure
Amplify Desmos Math combines the best of problem-based lessons, intervention, personalized practice, and assessments into a coherent and engaging experience for both students and teachers.
Lessons and units in Amplify Desmos Math California are designed around a Proficiency Progression, a model that steps out problem-based learning by systematically building students’ curiosity into lasting grade-level understanding.
In the Proficiency Progression, lessons begin by activating students’ natural curiosity and offering opportunities to generate new ideas through collaboration. Teachers are then able to refine ideas through intentional facilitation and guide students to grade-level understanding, while students retain the ability to use different strategies and methods to show their comprehension of the content. Students are provided ample opportunities to develop lasting understanding.
Scope and Sequence
Below you can view the scope and sequence for Amplify Desmos Math California Math 1.
Lesson Design and Structure
Amplify Desmos Math California is designed with a structured approach to problem-based learning that systematically builds on students’ curiosity and allows students to grapple with the Big Ideas of the California Framework. Every lesson activity is organized into a Launch, Monitor, Connect format.
Launch: The launch is a short, whole-class conversation that creates a need or excitement, provides clarity, or helps students connect their prior knowledge or personal experience, which ensures that everyone has access to the upcoming work.
Monitor: As students work individually, in pairs, or in groups, teachers explore student thinking, ask questions, and provide support to help move the conversations closer to the intended math learning goal.
Connect: Teachers connect students’ ideas to the key learning goals of the lesson, facilitating class discussions that help synthesize and solidify the Big Ideas.
Each lesson within Amplify Desmos Math California follows the same structure.
Warm-Up: Every Amplify Desmos Math California lesson begins with a whole class Warm-Up. Warm-Ups are an invitational Instructional Routine intended to provide a social moment at the start of the lesson in which every student has an opportunity to contribute. Warm-Ups may build fluency or highlight a strategy that may be helpful in the current lesson or act as an invitation into the math of the lesson.
Lesson Activities: Each lesson includes one or two activities. These activities are the heart of each lesson. Students notice, wonder, explore, calculate, predict, measure, explain their thinking, use math to settle disputes, create challenges for their classmates, and more. Guidance is provided to help teachers launch, monitor, and connect student thinking over the course of the activity.
Synthesis and Show What You Know: The Synthesis is an opportunity for the teacher and students to pull all the learning of the lesson together into a lesson takeaway. Students engage in a facilitated discussion to consolidate and refine their ideas about the learning goals, and the teacher synthesizes students’ learning. Show What You Know is a daily assessment opportunity for students to show what they know about the learning goals and what they are still learning.
Practice and Differentiation: Daily practice problems for the day’s lesson are included both online and in the print Student Edition, including fluency, test practice, and spiral review.
Routines
Amplify Desmos Math California features a variety of lesson routines. Instructional routines and Math Language Routines (MLRs) are used within lessons to highlight student-developed language and ideas, cultivate conversation, support mathematical sense-making, and promote meta-cognition. Both are called out at point-of-use within the Teacher Edition and Teacher Presentation Screens. Below are the types of routines used throughout the Amplify Desmos Math California curriculum:
Math Language Routines
- MLR1: Stronger and Clearer Each Time
- MLR2: Collect and Display
- MLR3: Critique, Correct, Clarify
- MLR5: Co-Craft Questions
- MLR6: Three Reads
- MLR7: Compare and Connect
- MLR 8: Discussion Supports
Instructional Routines
- Decide and Defend
- Notice and Wonder
- Number Talk
- Tell a Story
- Think-Pair-Share
- Which One Doesn’t Belong?
Category 3: Assessments
A variety of performance data in Amplify Desmos Math California provides evidence of student learning, while helping students bolster their skills and understanding.
Unit-Level Assessment
Amplify Desmos Math California has embedded unit assessments that offer key insights into students’ conceptual understanding of math. These assessments provide regular, actionable information about how students are thinking about and processing math, with both auto-scoring and in-depth rubrics that help teachers anticipate and respond to students’ learning needs.
Pre-Unit Check: Each unit begins with a formative assessment designed to identify the student skills that will be particularly relevant to the upcoming unit. This check is agnostic to the standards covered in the following unit and serves not as a deficit-based acknowledgment of what students do not know, but rather as an affirmation of the knowledge and skills with which students come in.
End-of-Unit Assessment: Students engage with rigorous grade-level mathematics through a variety of formats and tasks in the summative End-of-Unit Assessment. A combination of auto-scored (when completed digitally) and rubric-scored items provides deep insights into student thinking. All Amplify Desmos Math California End-of-Unit Assessments include two forms.
Sub-Unit Quizzes: Sub-Unit Quizzes are formative assessments embedded regularly in Math 1. In these checks, students are assessed on a subset of conceptual understandings from the unit, with rubrics that help illuminate students’ current understanding and provide guidance for responding to student thinking.
Performance Tasks: At the end of each unit there is a summative assessment performance task provided to evaluate students’ proficiency with the concepts and skills addressed in the unit.
Lesson-Level Assessments
Amplify Desmos Math California lessons include daily moments of assessment to provide valuable evidence of learning for both the teacher and student. Beyond formative, summative, and benchmark assessments, students also have opportunities for self-reflection with Watch Your Knowledge Grow. Students take ownership of their learning by reflecting and tracking their progress before and after each unit.
Show What You Know: Each lesson has a daily formative assessment focused on one of the key concepts in the lesson. Show What You Know moments are carefully designed to minimize completion time for students while maximizing daily teacher insights to attend to student needs during the following class.
Responsive Feedback™: Teachers have the ability to see and provide in-the-moment feedback as students progress through a digital lesson. Responsive Feedback motivates students and engages them in the learning process.
Diagnostic Assessment
Every grade level features an asset-based diagnostic assessment designed to be administered at the beginning of the year. Delivered digitally and to the whole class, our diagnostic assessment is uniquely designed to reveal underlying math thinking and identify what students know about grade-level math. With data beyond just right and wrong, teachers have the type of deeper level of insights need to take the right next step.
CAASPP-Aligned Assessment Preparation
Amplify Desmos Math is designed to support students’ mathematical development through problem-based learning, differentiation, and embedded assessments. The program’s emphasis on conceptual understanding, procedural fluency, and application aligns with the mathematical practices and content standards assessed by the CAASPP.
Amplify Desmos Math California includes a CAASPP-aligned Item Bank. This standards-aligned bank of questions allows teachers to filter and search by grade and standard to find items. Once assigned on the digital platform, students will experience CAASPP-like practice with the online digital tools.
Data and Reporting
Amplify Desmos Math California provides teachers and administrators with unified reporting and insights so that educators have visibility into what students know about grade-level math—and can plan instruction accordingly for the whole class, small groups, and individual students. Reporting functionality integrates unit assessments, lesson assessments, diagnostic data, and progress monitoring for a comprehensive look at student learning. Program reports show proficiency and growth by domain, cluster, standard, and priority concept using performance data from unit assessments, then highlight areas of potential student need to allow teachers to modify their instruction and target differentiated support.
Administrator reporting provides a complete picture of student, class, and district performance, allowing administrators to implement instructional and intervention plans.
Category 4: Access and Equity
The Amplify Desmos Math California curriculum provides teachers with lessons, strategies, and resources to eliminate barriers and increase access to grade-level content without reducing the mathematical demand of tasks. Our lessons are developed using the Universal Design for Learning (UDL) framework to proactively ensure that all learners can access and participate in meaningful, challenging learning opportunities.
Every activity has multiple entry points to ensure that all students are supported and challenged. Intervention and personalized learning activities are directly connected to the day’s content and offer students the individualized supports they need to be successful.
Each lesson and unit contains guidance for teachers on how to identify students who may need support, students who need to keep strengthening their understanding, and students who may be ready to stretch their learning. In addition, teachers are provided with recommendations for resources to use with each group of students.
Universal Design for Learning
Each lesson in the program incorporates opportunities for engagement, representation, action, and expression based on the guidelines of Universal Design for Learning (UDL).
- Multiple Means of Engagement: Students engage in both print and digital learning, and are regularly participating in discussions and hands-on activities. Students are invited to build their own challenge for other students to solve, which provides opportunities for choice and
autonomy, as well as joy and play. - Multiple Means of Representation: Students are encouraged to demonstrate their learning using mathematical representations, both print and digital, and regularly engage with their peers in analyzing multiple possible solutions. Classes engage in open-ended discussions about what individual students notice and wonder about mathematical concepts.
- Multiple Means of Action and Expression: Learners differ in how they navigate learning environments and express what they know. Students can communicate their ideas in multiple ways, including in print, sketching, uploading photos, or recording an audio response.
Accessibility
Lesson Facilitation Supports
Every lesson includes at least one specific suggestion the teacher can use to increase access to the lesson without reducing the mathematical demand of the tasks. These suggestions address the following areas:
- Conceptual Processing
- Visual-Spatial Processing
- Executive Functioning
- Memory and Attention
- Fine Motor Skills
Accessibility Tools
Students have the ability to control accessibility tools so that each learning experience is customized to their individual needs. In many instances, these tools can be turned on or off at any point of instruction.
- Text to speech: Reads text instructions to students in multiple languages
- Enlarged font: Increases the size of all text on screen
- Braille mode: Includes narration of digital interactions
- Language selection: Toggles between languages
Differentiation: In-Lesson Teacher Moves
Within every lesson activity, teachers can use the suggestions in the Differentiation Teacher Moves table to provide in-the-moment instructional support while students are engaged in the work of the lesson. This table can help teachers anticipate the ways students may approach the activity, and provides prompts that they can use during the lesson to Support, Strengthen, and Stretch individual students in their thinking. Teachers are provided with clear student actions and understanding to look for, each matched with immediately usable suggestions for how to respond to the student thinking illustrated in each row of the table. In addition to using these suggestions in the moment as teachers monitor student work, teachers can review the Differentiation table in advance to help them anticipate how students are likely to approach the activity.
Differentiation: Beyond the Lesson
Teachers are provided with recommendations for resources to use with each group of students needing support, strengthening, and stretching after each lesson. Support, Strengthen, and Stretch resources include:
- Mini-Lessons: 15-minute, small-group direct instruction lessons targeted to a specific concept or skill
- Item Banks: Space for teachers to create practice and assessments by using filters and searching for standards, summative-style items, and more
- Fluency Practice: Adaptive, personalized practice built out for basic operations and more
- Extensions: Lesson-embedded Teacher Moves including possible stretch questions and activities for students
- Lesson Practice: Additional practice problems support every lesson
- Math Adventures: Strategy-based math games where students engage with math concepts and practice skills in a fun digital environment
- Lesson Summary Support: Support for students and caregivers that provides efficient explanation of the learning goal with clear examples
Math Identity and Community
The Math Identity and Community feature supports teachers in helping students build confidence in their own mathematical thinking, develop skills to work with and learn from others when doing math, and learn how math is an interwoven part of their broader community. The embedded prompts throughout the lessons are designed to highlight what it means to be good at math, the value of sharing ideas, and the power of flexible and creating thinking. Here are some examples of the Math Identity and Community supports embedded in each lesson:
- I can be all of me in math class. You will work with partners every day in math class. What do you want your partners to know about you?
- We are a math community. What does good listening look like and sound like in a math community?
- I am a doer of math. What math strengths did you use today?
Math Language Development
Every lesson in Amplify Desmos Math California includes opportunities for all students to develop mathematical language as they experience the content. Amplify Desmos Math California purposefully progresses language development from lesson to lesson and across units by supporting students in making their arguments and explanations stronger, clearer, and more precise. This systematic approach to the development of math language can be broken down into the following four categories of support:
- Vocabulary: Units and lessons start by surfacing students’ language for new concepts, then building connections between their language and the new vocabulary for that unit. This honors the language assets that students bring into their learning.
- Language Goals: Language goals attend to the mathematics students are learning, and are written through the lens of one or more of four language modalities: reading, writing, speaking, and listening.
- Math Language Routines: Math Language Routines are used within lessons to highlight student-developed language and ideas, cultivate conversation, support mathematical sense-making, and promote meta-cognition.
- Multilingual/English Learner Supports: Supports for multilingual/English learners (ML/ELs) are called out at intentional points within each lesson. These specific, targeted suggestions support ML/ELs with modifications that increase access to a task, or through development of contextual or mathematical language (both of which can be supportive of all learners).
Multilingual and English Learner Supports
Partnership with English Learner Success Forum
Amplify partnered with the English Learner Success Forum (ELSF), a national nonprofit organization that advocates for high-quality instructional materials that are inclusive of multilingual learners. ELSF reviewed Amplify Desmos Math California, and provided directional guidance and feedback to ensure that the program reflects their research-based instructional strategies for multilingual/English learners.
Math Language Development Resource
Our Math Language Development Resources book contains lesson-specific strategies and activities for all levels of English Learners (i.e., Emerging, Expanding, Bridging). With support for every lesson, teachers are empowered to help all students, regardless of their language skills, to participate fully, grasp the material, and excel in their mathematical journey.
Multilingual Glossary
Amplify Desmos Math California includes a digital glossary for languages other than Spanish. Translations will be provided for up to nine languages.
Spanish Version
Amplify Desmos Math California will include Spanish student-facing materials beginning in the 2026–27 school year.
Category 5: Instructional Planning and Support
Amplify Desmos Math California includes a variety of embedded instructional supports to empower teachers to lead effectively and gain actionable insights into student growth and progress. Teachers are equipped with a comprehensive set of resources designed to fulfill the requirements of Category 5.
Grade-level concepts
Within the Teacher Edition front matter:
- Scope and sequence
- Big Ideas, Drivers of Investigation, and Content Connections
- Grade level standards
- Standards for Mathematical Practice
- English Language Development Standards
- Environmental Principals and Concepts
Within each Unit and Sub-Unit Overview:
- Big Ideas, Drivers of Investigation, and Content Connections
- Math that Matters Most
- Grade level standards
- Standards for Mathematical Practice
- English Language Development Standards
- Environmental Principals and Concepts
Within each Lesson:
- Big Ideas, Drivers of Investigation, and Content Connections
- Grade level standards
- Standards for Mathematical Practice
- English Language Development Standards
- Environmental Principals and Concepts
How to implement the program
At the course level (within the Teacher Edition front matter):
- Navigating the Program (both print and digital)
- Facilitating Lesson Activities with Launch, Monitor and Connect
- Overview of the Digital Facilitation Tools
At the lesson level:
- Suggestions for timing
- What materials to prep
- How to organize and group students
- Key lesson takeaways with the Synthesis
- Recommendations for Differentiation
- Strategies for intervention and extensions (in the Intervention, Extensions, and Investigation Resources book)
At the activity level:
- Differentiation recommendations
- Accessibility tips
- ML / EL tips
- Teacher look-fors
- Recommended Teacher Moves
- Prompts for guiding student thinking
- Sample student responses
Development of Math Language
A variety of language development supports are provided within the Student and Teacher Editions and Math Language Development Resources book.
At the lesson level:
- Diagrams and visuals
- Sentence frames and word banks
- Graphic organizers, including Frayer models
- Vocabulary routines
- Embedded language supports aligned to the CA ELDs
- Lesson-specific strategies for Emerging, Expanding, and Bridging
At the unit level:
- Words With Multiple Meanings
- Contextual vocabulary
At the course level:
- English/Spanish cognates
- Multilingual Glossary
Other Curriculum Guidance
- Additional Practice Resources book
- Assessment Resources book
- Assess and Respond guidance paired with each assessment opportunity
- Show-What-You-Know activities
- Answer keys and rubrics
- Performance tasks
Survey
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Program overview
Boost Lectura is a high-quality, personalized Spanish literacy foundational skills program that complements Amplify Reading to build reading proficiency in both English and Spanish for grades K–2.
Student field study experience
Note: This is an early subset of the program experience. Some content may be appropriate for some students, but difficult for others. This is feedback we want to hear. The designs are also still in progress, with many aspects yet to be featured. Please email Aya Bukres with all suggestions!
Field study books and games
Below is a list of books and games (with associated skills) by grade level. Students will access these games and books through Quests.
Note: Books do not include voice-over at this time.
Kindergarten Books
| ¿Qué pasa con la gallina Tina? | ¿Qué puedes hacer con los 5 sentidos? | ¿Por qué croan las ranas? |
| Un festín de sabores | Un ¡pop! en tiempo | Los aluxes |
| El efecto mariposa | Las estaciones del año |
Kindergarten Games
| Game Name | Big Idea | Skill that will be practiced |
| Son sabrosón | Phonological Awareness | Rhyming |
| Alfa y beto | Phonological Awareness | Blending |
| Jugando ando | Phonological Awareness | Segmentation |
| Tragaletras exigentes | Phonics | Letter-sound correspondences |
| Tragaletras gruñones | Phonics | Letter combinations |
| Tragaletras comelones | Phonics | Review of letter-sound correspondences and letter combinations |
| Investiga la escena | Comprehension Processes | Gap-filling Inferences |
Grade 1 Books
| La leyenda de la colibrí | La capibara: Un animal amigable | Mi ruidoso cuerpo |
| El zorro y el huaychao | Deseos al sol |
Grade 1 Games
| Game Name | Big Idea | Skill that will be practiced |
| Alfa y beto | Phonological Awareness | Blending |
| Jugando ando | Phonological Awareness | Segmentation |
| Tragaletras exigentes | Phonics | Letter-sound correspondences |
| Tragaletras gruñones | Phonics | Letter combinations |
| Tragaletras comelones | Phonics | Review of letter-sound correspondences and letter combinations |
| Silabalón: la copa | Phonics | Syllable decoding |
| ¿Aquí o alla? | Phonics & Word Recognition | Decoding words with y, g, and c |
| ¿Esta o aquella? | Phonics & Word Recognition | Decoding words with different graphemes to represent the same phoneme |
| ¡Abra palabra! | Phonics & Word Recognition | Decoding – syllable manipulation |
| Quita y pon | Phonics & Word Recognition | Decoding – syllable manipulation |
| ¡Conéctalo! | Comprehension Processes | Using connectives |
| Investiga la escena | Comprehension Processes | Gap-filling inferences |
Grade 2 Books
| La despedida | La verdadera fortuna | La fascinante Ruta de la Seda |
| Bernardo de Gálvez | Hormigas amigas |
Grade 2 Games
| Game Name | Big Idea | Skill that will be practiced |
| ¿Aquí o alla? | Phonics & Word Recognition | Decoding words with y, g, and c |
| ¿Esta o aquella? | Phonics & Word Recognition | Decoding words with different graphemes to represent the same phoneme |
| ¡Abra palabra! | Phonics & Word Recognition | Decoding – syllable manipulation |
| Quita y pon | Phonics & Word Recognition | Decoding – syllable manipulation |
| ¡Conéctalo! | Comprehension Processes | Using connectives |
| Investiga la escena | Comprehension Processes | Gap-filling inferences |
Consider using Boost Lectura during the following times:
- Small group or center time
- Choice time
- During intervention blocks
- After school
- At home
- Remote learning
Getting your students online
Instruct students to navigate to learning.amplify.com, and log in using the method you typically use when logging into Boost Reading.
Find and click on the icon for Boost Lectura, as shown above.
At this time, students can begin playing games or reading books by clicking on “Iniciar.”
Having students play games in Quests
Select a game from the list to play!
Students can play games in Quests by selecting the curioso icon.
Students should hear quest narratives in Spanish.
The Automatic Placement Tool (APT)
The Automatic Placement Tool will be served when students first log in and choose the Lectura product. The Experience should take about 15–20 minutes total.
Students are greeted with a comical animation explaining we need their help with answering a few questions.
Students are guided through a few short activities measuring different skills domains.
Students receive closure to their experience via another short animation.
Troubleshooting guide
Please check to ensure “cookies” are accepted on your device.
If you still receive an error message or blank screen when accessing an Amplify page, please email Aya Bukres.
Please email Aya Bukres to confirm your login credentials.
Math strategies that build community in your classroom
It’s tough to do math without sets, sums, and multipliers, so it stands to reason that it’d be tough to learn math solo, outside of a group.
Indeed, research shows that math is best learned in a community. In this post, we’ll explain why that is, what it looks like in a classroom, and how you can create a community for your math students.
What math community means: Creative classroom ideas
There are many types of math communities: online interest groups, professional organizations, the Mathletes.
In the context of a math classroom, a math community refers to the collaborative environment a teacher can create using both math strategies and social strategies (and by involving students’ parents and guardians). In a robust math community, all students feel comfortable sharing ideas, asking questions, and engaging in mathematical conversations.
In other words, math communities are student-centered. Rather than delivering information, teachers guide students. They encourage students to explore math concepts, make connections to the real world, and ask questions—of each other, and the teacher.
And in a math community, wrong answers aren’t dismissed—in fact, they’re an essential part of the learning process. In our webinar What Amazing K–12 Math Looks Like, educator and director of research at Desmos, Dan Meyer underlines the importance of students understanding “the value in their thinking—which means the value in their wrong answers.”
Benefits of math community: Equity in schools and more
A community-oriented math classroom can help each student learn, and all students learn. Here’s how.
- Increased engagement. When students feel a sense of belonging and connection in their math class, they’re more likely to be engaged and motivated. By promoting open discussions, group activities, and cooperative problem-solving, teachers can help students—even those who don’t think they’re “math people”—develop a genuine interest in math.
- Reduced math anxiety. Math anxiety affects at least 20% of students. It can hinder their growth in math and beyond. But in a supportive math community—where different styles and wrong answers are considered part of the process—those students can thrive. Embracing and working from incorrect answers encourages students to focus on the “how” of math, and to participate without fear of getting it wrong. They feel more comfortable asking questions, taking risks, and making mistakes as well as learning from them.
- Improved communication skills. In a math community, all students get the chance to communicate their mathematical thinking and reasoning. Explaining their ideas to others and listening to their classmates enhances their speaking and writing skills—in math, and across other subjects, too.
- Learning from diverse perspectives. A supportive math classroom community allows students from different backgrounds and with varying abilities to contribute to class and feel valued. Encouraging—and observing—the sharing of diverse perspectives fosters critical thinking, creativity, and problem-solving skills.
- Positive reinforcement. A strong math community creates an environment where students feel valued, respected, included, and supported. It’s fertile ground for a growth mindset, one in which students believe they actually can do math regardless of challenges or errors. A math community encourages risk-taking, resilience, and perseverance—in math, and beyond.
How to engage students in math lessons that build community
Want to know how to make math fun and build community? Here are some ways to get started.
- Encourage collaboration. Promote a culture of cooperation and teamwork by incorporating group activities, peer support, and class discussions into your lessons.
- Celebrate brilliance. Recognize a variety of efforts, insights, and accomplishments among students—including taking risks, and making mistakes. This will motivate all students to appreciate different ways of learning and the value of both process and product.
- Personalize support. Offering individualized help to students who need it shows commitment to their success and builds a supportive environment for everyone.
- Develop a growth mindset. Create a culture where mistakes are inevitable, even welcomed, as part of the learning process. Encourage perseverance and persistence.
- Choose meaningful tasks. Assign problems with real-world relevance. Working together to solve them helps students see the “why” of math—and connect with each other in the process.
- Play. Game-ifying problems and introducing friendly competition builds camaraderie and helps students find shared joy in math—a win-win!
More to explore
The Science of Writing: Key to mastering reading
We know that “reading, writing, and ‘rithmetic” doesn’t cover all the core skills students must learn in school. Still, it’s easy to sense in our gut why reading and writing come first—and together. Reading and writing reinforce each other.
The way we now understand these two skills and how kids learn them is connected, too. That is, the Science of Reading and the Science of Writing are also linked, and invaluable. According to the National Assessment of Educational Progress (NAEP), only 27% of 12th graders achieved a proficient level in writing in 2011.
The key to unlocking literacy success resides not just in understanding the Science of Writing, but also in acknowledging its dynamic connection to the Science of Reading.
Connecting writing with literacy development
The Science of Reading refers to the vast collection of evidence-based practices that explore and explain how kids learn to read and form the foundation for literacy instruction that works. It emphasizes key components such as phonemic awareness, phonics, fluency, vocabulary, and comprehension. It stipulates that—no matter what magical worlds reading unlocks—reading instruction must be systematic and intentional.
The Science of Reading clearly indicates how best to support students as they learn to read. But reading is only half of the literacy equation. What about writing?
Akin to the Science of Reading, the Science of Writing refers to the body of research that examines effective writing instruction and the processes involved in developing writing skills. It emphasizes explicit, systematic teaching of writing structures, strategies, and conventions—again, similar to the Science of Reading’s approach. This includes understanding the cognitive processes behind planning, drafting, revising, and editing, as well as the development of handwriting, grammar, and composition skills.
The Science of Writing also highlights the importance of integrating writing with reading instruction. It enhances comprehension and communication abilities by reinforcing language skills through practical application.
Using instruction based on the Science of Writing can transform student communication, making it clearer, more effective, and more creative—opening up new worlds of connection, expression, and opportunity. Indeed, the 2024 survey by The National Association of Colleges and Employers found that 73% of employers look for written communication skills when selecting candidates to hire.
Effective instruction: Why teach writing and reading in tandem
This doesn’t mean that we should use evidence-based methods to teach reading in the morning, and then evidence-based methods to teach writing in the afternoon.
An integrated approach to reading and writing isn’t just beneficial—it’s essential. These two facets of literacy are interwoven processes that enhance each other. The more students read, the more they know. And a robust knowledge base helps students become not only stronger readers, but also stronger writers.
When students read a variety of texts, they absorb different writing styles, sentence structures, and vocabularies, which can serve as models for their own writing. Reading instruction based in the Science of Reading can also help students address writing problems and challenges. And writing about what they read also helps students deepen their capacity for both comprehension and expression.
Explicit and structured writing instruction is necessary for all students to be successful writers, as well as successful readers. When students write, they employ the same comprehension skills they use in reading.
How to teach writing and reading together
Here are just a few strategies to consider:
- Inspiration through imitation. Use reading materials as models for writing assignments. Encourage students to mimic sentence structures or vocabulary from texts they read.
- Read and respond: After reading, have students engage in response writing. This practice not only sharpens writing skills, but also reinforces comprehension by encouraging reflection and analysis.
- Instruct on structure. Introduce students to the writing process: prewriting/outlining, drafting, revising, and editing. These steps parallel the cognitive processes students use when understanding complex texts.
To learn more about reading, writing, and realizing every student’s full potential, check out:
Amplify Desmos Math California
Welcome, Algebra 1 Reviewers!
We’re honored to introduce you to Amplify Desmos Math California. We’re confident you’ll find this comprehensive program to be a powerful tool for bringing the vision of the California Math Framework to life in classrooms across the state.
Please start with the video on the right to learn how to navigate the program and access key features referenced within our submission. Below you’ll find additional resources to support your review.
Your Review Samples
As a curriculum that incorporates both print and digital resources, it’s important that you explore both our physical materials (delivered to you in grade-specific tubs) and our digital materials (accessible through our platform). We invite you to explore both types of resources using the instructions and tips below.
Print Samples
Your print samples should have arrived in grade-specific tubs with a copy of your Reviewer Binder contained within the Algebra 1 shipping box. As you begin the process of organizing your materials, please refer to the inventory checklist found inside the tub as well as within your Reviewer Binder.
Digital Samples
In order to access your digital samples, you’ll need to log into our platform using your unique login credentials found on a Digital Access Flyer inside of your Reviewer Binder. Once you have located the flyer:
- Click the orange button below to access the platform.
- Click “Log in with Amplify.”
- Enter the username and password provided on your Digital Access Flyer.
Navigation Tips
Below you will find helpful tips for navigating Amplify Desmos Math California. We recommend reading these pages alongside the program’s print materials and digital experience to gain a deeper understanding of the program.
Click the links below to read about navigating program features including:
Built for California
The Amplify Desmos Math California program is designed around the vision articulated in the California Mathematics Framework to enable all California students to become powerful users of mathematics. Our program incorporates the latest research in student learning, meaning that we:
- Focus on the Big Ideas: Amplify Desmos Math California’s courses, units, and lessons are centered around the Big Ideas. Big Ideas, like standards, are not considered in isolation. In addition to each unit and lesson’s focal Big Ideas, Amplify Desmos Math California also provides connections among the Big Ideas across units and lessons.
- Center on open and engaging tasks: Amplify Desmos Math California is grounded in engaging tasks meant to address students’ often-asked question: “Why am I learning this?” Students are invited into learning with low-floor, high-ceiling tasks that provide an entry point for all. Open tasks in Amplify Desmos Math California provide the space for students to try on multiple strategies and represent their thinking in different ways, and allow student explanation and discussion to serve as the center of the classroom. All lessons offer both print and digital representations of lessons.
- Provide enhanced digital experiences: Amplify Desmos Math California includes digitally-enhanced lesson activities, incorporating interactive digital tools alongside print materials. These purposefully-placed resources allow students to visualize mathematical concepts, receive actionable feedback while practicing, encounter personalized learning support from an onscreen tutor, and engage in discussions about their thinking and approaches.
- Treat core instruction and differentiation as integral partners: The Amplify Desmos Math California curriculum provides teachers with lessons, strategies, and resources to eliminate barriers and increase access to grade-level content without reducing the mathematical demand of tasks. Every activity has multiple entry points to ensure that all students are supported and challenged. Intervention and personalized learning activities are directly connected to lesson content and offer students the individualized support as they dive into the mathematics.
Category 1: Mathematics Content/Alignment with the Standards
Standards Map
Linked here is the Standards Map for Amplify Desmos Math California for Algebra 1.
Evaluation Criteria Map
Linked here is the Evaluation Criteria Map Algebra 1. Please note that you will need to be logged into the digital platform to access the links in the Evaluation Criteria Map.
Standards for Mathematical Practice
Linked here is the alignment of Amplify Desmos Math California to the Standards for Mathematical Practice at Algebra 1.
Drivers of Investigation and Content Connections
Amplify Desmos Math California incorporates the Drivers of Investigation (DIs) and Content Connection (CCs) throughout the program. Throughout the year, students engage with open and authentic tasks of varying durations — from lesson activities to unit-level Explore lessons and longer course-level Investigations. Every lesson and investigation opportunity is grounded around the why, how, and what of the learning experience, and helps teachers bring mathematical concepts to life.
California English Language Development Standards
Linked here is the alignment of Amplify Desmos Math California to the California English Language Development Standards for Algebra 1.
California Environmental Principles and Concepts
Select lessons, performance tasks, and investigations across grade levels in Amplify Desmos Math California are aligned to one or more of the California Environmental Principles and Concepts. Click this link to view how the California Environmental Principles and Concepts are represented in Amplify Desmos Math California Algebra 1.
Category 2: Program Organization
Amplify Desmos Math California thoughtfully combines conceptual understanding, procedural fluency, and application. Each lesson is designed to tell a story by posing problems that invite a variety of approaches before guiding students to synthesize their understanding of the learning goals.
Big Ideas
Amplify Desmos Math California’s courses, units, and lessons are centered around the Big Ideas. Big Ideas, like standards, are not considered in isolation. In addition to each unit and lesson’s focal Big Ideas, Amplify Desmos Math California also provides connections among the Big Ideas across units and lessons. Please refer to Keeping the Big Ideas at the Center, linked here, for the Amplify Desmos Math California Algebra 1 lesson design and alignment to the Big Ideas.
Program Structure
Amplify Desmos Math California combines the best of problem-based lessons, intervention, personalized practice, and assessments into a coherent and engaging experience for both students and teachers.
Lessons and units in Amplify Desmos Math California are designed around a Proficiency Progression, a model that steps out problem-based learning by systematically building students’ curiosity into lasting grade-level understanding.
In the Proficiency Progression, lessons begin by activating students’ natural curiosity and offering opportunities to generate new ideas through collaboration. Teachers are then able to refine ideas through intentional facilitation and guide students to grade-level understanding, while students retain the ability to use different strategies and methods to show their comprehension of the content. Students are provided ample opportunities to develop lasting understanding.
Scope and Sequence
Below you can view the scope and sequence for Amplify Desmos Math California Algebra 1.
Lesson Design and Structure
Amplify Desmos Math California is designed with a structured approach to problem-based learning that systematically builds on students’ curiosity and allows students to grapple with the Big Ideas of the California Framework. Every lesson activity is organized into a Launch, Monitor, Connect format.
Launch: The launch is a short, whole-class conversation that creates a need or excitement, provides clarity, or helps students connect their prior knowledge or personal experience, which ensures that everyone has access to the upcoming work.
Monitor: As students work individually, in pairs, or in groups, teachers explore student thinking, ask questions, and provide support to help move the conversations closer to the intended math learning goal.
Connect: Teachers connect students’ ideas to the key learning goals of the lesson, facilitating class discussions that help synthesize and solidify the Big Ideas.
Each lesson within Amplify Desmos Math California follows the same structure.
Warm-Up: Every Amplify Desmos Math California lesson begins with a whole class Warm-Up. Warm-Ups are an invitational Instructional Routine intended to provide a social moment at the start of the lesson in which every student has an opportunity to contribute. Warm-Ups may build fluency or highlight a strategy that may be helpful in the current lesson or act as an invitation into the math of the lesson.
Lesson Activities: Each lesson includes one or two activities. These activities are the heart of each lesson. Students notice, wonder, explore, calculate, predict, measure, explain their thinking, use math to settle disputes, create challenges for their classmates, and more. Guidance is provided to help teachers launch, monitor, and connect student thinking over the course of the activity.
Synthesis and Show What You Know: The Synthesis is an opportunity for the teacher and students to pull all the learning of the lesson together into a lesson takeaway. Students engage in a facilitated discussion to consolidate and refine their ideas about the learning goals, and the teacher synthesizes students’ learning. Show What You Know is a daily assessment opportunity for students to show what they know about the learning goals and what they are still learning.
Practice and Differentiation: Daily practice problems for the day’s lesson are included both online and in the print Student Edition, including fluency, test practice, and spiral review.
Routines
Amplify Desmos Math California features a variety of lesson routines. Instructional routines and Math Language Routines (MLRs) are used within lessons to highlight student-developed language and ideas, cultivate conversation, support mathematical sense-making, and promote meta-cognition. Both are called out at point-of-use within the Teacher Edition and Teacher Presentation Screens. Below are the types of routines used throughout the Amplify Desmos Math California curriculum:
Math Language Routines
- MLR1: Stronger and Clearer Each Time
- MLR2: Collect and Display
- MLR3: Critique, Correct, Clarify
- MLR5: Co-Craft Questions
- MLR6: Three Reads
- MLR7: Compare and Connect
- MLR 8: Discussion Supports
Instructional Routines
- Decide and Defend
- Notice and Wonder
- Number Talk
- Tell a Story
- Think-Pair-Share
- Which One Doesn’t Belong?
Category 3: Assessments
A variety of performance data in Amplify Desmos Math California provides evidence of student learning, while helping students bolster their skills and understanding.
Unit-Level Assessment
Amplify Desmos Math California has embedded unit assessments that offer key insights into students’ conceptual understanding of math. These assessments provide regular, actionable information about how students are thinking about and processing math, with both auto-scoring and in-depth rubrics that help teachers anticipate and respond to students’ learning needs.
Pre-Unit Check: Each unit begins with a formative assessment designed to identify the student skills that will be particularly relevant to the upcoming unit. This check is agnostic to the standards covered in the following unit and serves not as a deficit-based acknowledgment of what students do not know, but rather as an affirmation of the knowledge and skills with which students come in.
End-of-Unit Assessment: Students engage with rigorous grade-level mathematics through a variety of formats and tasks in the summative End-of-Unit Assessment. A combination of auto-scored (when completed digitally) and rubric-scored items provides deep insights into student thinking. All Amplify Desmos Math California End-of-Unit Assessments include two forms.
Sub-Unit Quizzes: Sub-Unit Quizzes are formative assessments embedded regularly in Algebra 1. In these checks, students are assessed on a subset of conceptual understandings from the unit, with rubrics that help illuminate students’ current understanding and provide guidance for responding to student thinking.
Performance Tasks: At the end of each unit there is a summative assessment performance task provided to evaluate students’ proficiency with the concepts and skills addressed in the unit.
Lesson-Level Assessments
Amplify Desmos Math California lessons include daily moments of assessment to provide valuable evidence of learning for both the teacher and student. Beyond formative, summative, and benchmark assessments, students also have opportunities for self-reflection with Watch Your Knowledge Grow. Students take ownership of their learning by reflecting and tracking their progress before and after each unit.
Show What You Know: Each lesson has a daily formative assessment focused on one of the key concepts in the lesson. Show What You Know moments are carefully designed to minimize completion time for students while maximizing daily teacher insights to attend to student needs during the following class.
Responsive Feedback™: Teachers have the ability to see and provide in-the-moment feedback as students progress through a digital lesson. Responsive Feedback motivates students and engages them in the learning process.
Diagnostic Assessment
Every grade level features an asset-based diagnostic assessment designed to be administered at the beginning of the year. Delivered digitally and to the whole class, our diagnostic assessment is uniquely designed to reveal underlying math thinking and identify what students know about grade-level math. With data beyond just right and wrong, teachers have the type of deeper level of insights need to take the right next step.
CAASPP-Aligned Assessment Preparation
Amplify Desmos Math is designed to support students’ mathematical development through problem-based learning, differentiation, and embedded assessments. The program’s emphasis on conceptual understanding, procedural fluency, and application aligns with the mathematical practices and content standards assessed by the CAASPP.
Amplify Desmos Math California includes a CAASPP-aligned Item Bank. This standards-aligned bank of questions allows teachers to filter and search by grade and standard to find items. Once assigned on the digital platform, students will experience CAASPP-like practice with the online digital tools.
Data and Reporting
Amplify Desmos Math California provides teachers and administrators with unified reporting and insights so that educators have visibility into what students know about grade-level math—and can plan instruction accordingly for the whole class, small groups, and individual students. Reporting functionality integrates unit assessments, lesson assessments, diagnostic data and progress monitoring for a comprehensive look at student learning. Program reports show proficiency and growth by domain, cluster, standard, and priority concept using performance data from unit assessments, then highlight areas of potential student need to allow teachers to modify their instruction and target differentiated support.
Administrator reporting provides a complete picture of student, class, and district performance, allowing administrators to implement instructional and intervention plans.
Category 4: Access and Equity
The Amplify Desmos Math California curriculum provides teachers with lessons, strategies, and resources to eliminate barriers and increase access to grade-level content without reducing the mathematical demand of tasks. Our lessons are developed using the Universal Design for Learning (UDL) framework to proactively ensure that all learners can access and participate in meaningful, challenging learning opportunities.
Every activity has multiple entry points to ensure that all students are supported and challenged. Intervention and personalized learning activities are directly connected to the day’s content and offer students the individualized supports they need to be successful.
Each lesson and unit contains guidance for teachers on how to identify students who may need support, students who need to keep strengthening their understanding, and students who may be ready to stretch their learning. In addition, teachers are provided with recommendations for resources to use with each group of students.
Universal Design for Learning
Each lesson in the program incorporates opportunities for engagement, representation, action, and expression based on the guidelines of Universal Design for Learning (UDL).
- Multiple Means of Engagement: Students engage in both print and digital learning, and are regularly participating in discussions and hands-on activities. Students are invited to build their own challenge for other students to solve, which provides opportunities for choice and autonomy, as well as joy and play.
- Multiple Means of Representation: Students are encouraged to demonstrate their learning using mathematical representations, both print and digital, and regularly engage with their peers in analyzing multiple possible solutions. Classes engage in open-ended discussions about what individual students notice and wonder about mathematical concepts.
- Multiple Means of Action and Expression: Learners differ in how they navigate learning environments and express what they know. Students can communicate their ideas in multiple ways, including in print, sketching, uploading photos, or recording an audio response.
Accessibility
Lesson facilitation supports
Every lesson includes at least one specific suggestion the teacher can use to increase access to the lesson without reducing the mathematical demand of the tasks. These suggestions address the following areas:
- Conceptual Processing
- Visual-Spatial Processing
- Executive Functioning
- Memory and Attention
- Fine Motor Skills
Accessibility tools
Students have the ability to control accessibility tools so that each learning experience is customized to their individual needs. In many instances, these tools can be turned on or off at any point of instruction.
- Text to speech: Reads text instructions to students in multiple languages
- Enlarged font: Increases the size of all text on screen
- Braille mode: Includes narration of digital interactions
- Language selection: Toggles between languages
Differentiation: In-Lesson Teacher Moves
Within every lesson activity, teachers can use the suggestions in the Differentiation Teacher Moves table to provide in-the-moment instructional support while students are engaged in the work of the lesson. This table can help teachers anticipate the ways students may approach the activity, and provides prompts that they can use during the lesson to Support, Strengthen, and Stretch individual students in their thinking. Teachers are provided with clear student actions and understanding to look for, each matched with immediately usable suggestions for how to respond to the student thinking illustrated in each row of the table. In addition to using these suggestions in the moment as teachers monitor student work, teachers can review the Differentiation table in advance to help them anticipate how students are likely to approach the activity.
Differentiation: Beyond the Lesson
Teachers are provided with recommendations for resources to use with each group of students needing support, strengthening, and stretching after each lesson. Support, Strengthen, and Stretch resources include:
- Mini-Lessons: 15-minute, small-group direct instruction lessons targeted to a specific concept or skill
- Item Banks: Space for teachers to create practice and assessments by using filters and searching for standards, summative-style items, and more
- Fluency Practice: Adaptive, personalized practice built out for basic operations and more
- Extensions: Lesson-embedded Teacher Moves including possible stretch questions and activities for students
- Lesson Practice: Additional practice problems support every lesson
- Math Adventures: Strategy-based math games where students engage with math concepts and practice skills in a fun digital environment
- Lesson Summary Support: Support for students and caregivers that provides efficient explanation of the learning goal with clear examples
Math Identity and Community
The Math Identity and Community feature supports teachers in helping students build confidence in their own mathematical thinking, develop skills to work with and learn from others when doing math, and learn how math is an interwoven part of their broader community. The embedded prompts throughout the lessons are designed to highlight what it means to be good at math, the value of sharing ideas, and the power of flexible and creating thinking. Here are some examples of the Math Identity and Community supports embedded in each lesson:
- I can be all of me in math class. You will work with partners every day in math class. What do you want your partners to know about you?
- We are a math community. What does good listening look like and sound like in a math community?
- I am a doer of math. What math strengths did you use today?
Math Language Development
Every lesson in Amplify Desmos Math California includes opportunities for all students to develop mathematical language as they experience the content. Amplify Desmos Math California purposefully progresses language development from lesson to lesson and across units by supporting students in making their arguments and explanations stronger, clearer, and more precise. This systematic approach to the development of math language can be broken down into the following four categories of support:
- Vocabulary: Units and lessons start by surfacing students’ language for new concepts, then building connections between their language and the new vocabulary for that unit. This honors the language assets that students bring into their learning.
- Language Goals: Language goals attend to the mathematics students are learning, and are written through the lens of one or more of four language modalities: reading, writing, speaking, and listening.
- Math Language Routines: Math Language Routines are used within lessons to highlight student-developed language and ideas, cultivate conversation, support mathematical sense-making, and promote meta-cognition.
- Multilingual/English Learner Supports: Supports for multilingual/English learners (ML/ELs) are called out at intentional points within each lesson. These specific, targeted suggestions support ML/ELs with modifications that increase access to a task, or through development of contextual or mathematical language (both of which can be supportive of all learners).
Multilingual and English Learner Supports
Partnership with English Learner Success Forum
Amplify partnered with the English Learner Success Forum (ELSF), a national nonprofit organization that advocates for high-quality instructional materials that are inclusive of multilingual learners. ELSF reviewed Amplify Desmos Math California, and provided directional guidance and feedback to ensure that the program reflects their research-based instructional strategies for multilingual/English learners.
Math Language Development Resource
Our Math Language Development Resources book contains lesson-specific strategies and activities for all levels of English Learners (i.e., Emerging, Expanding, Bridging). With support for every lesson, teachers are empowered to help all students, regardless of their language skills, to participate fully, grasp the material, and excel in their mathematical journey.
Multilingual glossary
Amplify Desmos Math California includes a digital glossary for languages other than Spanish. Translations will be provided for up to nine languages.
Spanish version
Amplify Desmos Math California will include Spanish student-facing materials beginning in the 2026–27 school year.
Category 5: Instructional Planning and Support
Amplify Desmos Math California includes a variety of embedded instructional supports to empower teachers to lead effectively and gain actionable insights into student growth and progress. Teachers are equipped with a comprehensive set of resources designed to fulfill the requirements of Category 5.
Grade-level concepts
Within the Teacher Edition front matter:
- Scope and sequence
- Big Ideas, Drivers of Investigation, and Content Connections
- Grade level standards
- Standards for Mathematical Practice
- English Language Development Standards
- Environmental Principals and Concepts
Within each Unit and Sub-Unit Overview:
- Big Ideas, Drivers of Investigation, and Content Connections
- Math that Matters Most
- Grade level standards
- Standards for Mathematical Practice
- English Language Development Standards
- Environmental Principals and Concepts
Within each Lesson:
- Big Ideas, Drivers of Investigation, and Content Connections
- Grade level standards
- Standards for Mathematical Practice
- English Language Development Standards
- Environmental Principals and Concepts
How to implement the program
At the course level (within the Teacher Edition front matter):
- Navigating the Program (both print and digital)
- Facilitating Lesson Activities with Launch, Monitor and Connect
- Overview of the Digital Facilitation Tools
At the lesson level:
- Suggestions for timing
- What materials to prep
- How to organize and group students
- Key lesson takeaways with the Synthesis
- Recommendations for Differentiation
- Strategies for intervention and extensions (in the Intervention, Extensions, and Investigation Resources book)
At the activity level:
- Differentiation recommendations
- Accessibility tips
- ML / EL tips
- Teacher look-fors
- Recommended Teacher Moves
- Prompts for guiding student thinking
- Sample student responses
Development of Math Language
A variety of language development supports are provided within the Student and Teacher Editions and Math Language Development Resources book.
At the lesson level:
- Diagrams and visuals
- Sentence frames and word banks
- Graphic organizers, including Frayer models
- Vocabulary routines
- Embedded language supports aligned to the CA ELDs
- Lesson-specific strategies for Emerging, Expanding, and Bridging
At the unit level:
- Words With Multiple Meanings
- Contextual vocabulary
At the course level:
- English/Spanish cognates
- Multilingual Glossary
Other Curriculum Guidance
- Additional Practice Resources book
- Assessment Resources book
- Assess and Respond guidance paired with each assessment opportunity
- Show-What-You-Know activities
- Answer keys and rubrics
- Performance tasks
Welcome, Idaho K-8 Science Reviewers!
Thank you for taking the time to review Amplify Science. On this site, you’ll find all the resources you need to learn more about this engaging and robust NGSS program. Below, you will also have the opportunity experience our program firsthand with a demo account to access the digital platform.
Amplify Science for grades K–8 has been rated all-green by EdReports. Read the review on EdReports.
Overview
With Amplify Science, students don’t just passively learn about science concepts. Instead, they take on the roles of scientists and engineers to actively investigate and make sense of real-world phenomena. They do this through a blend of cohesive and compelling storylines, hands-on investigations, collaborative discussions, literacy-rich activities, and interactive digital tools.
Listen to these educators share how the program empowers students to think, read, write, and argue like real scientists and engineers every day.
Grades K–5
Grades 6–8
Amplify Science Grades K-5 Tour for Idaho Educators
Amplify Science Grades 6-8 Tour for Idaho Evaluators
Program structure
Our cyclical lesson design ensures students receive multiple exposures to concepts through a variety of modalities. As they progress through the lessons within a unit, students build and deepen their understanding, increasing their ability to develop and refine complex explanations of the unit’s phenomenon. It’s this proven program structure and lesson design that enables Amplify Science to teach less, but achieve more.
Rather than asking teachers to wade through unnecessary content, we designed our program to address 100 percent of the NGSS and Idaho Standards in fewer days than other programs:
- In just 120 lessons at grades 6–8
- In just 66 lessons at grades K–2
- In just 88 lessons at grades 3–5
Unit types
Each unit delivers three-dimensional learning experiences and engages students in gathering evidence from a rich collection of sources, while also emphasizing a particular science and engineering practice.
Investigation units
Investigation units focus on the process of strategically developing investigations and gathering data to answer questions. Students are first asked to consider questions about what happens in the natural world and why, and are then involved in designing and conducting investigations that produce data to help answer those questions.
Modeling units
Modeling units provide extra support to students engaging in the practice of modeling. Students use physical models, investigate with computer models, and create their own diagrams to help them visualize what might be happening on the nanoscale.
Engineering Design units
Engineering design units provide opportunities for students to solve complex problems by applying science principles to the design of functional solutions, and iteratively testing those solutions to determine how well they meet preset criteria.
Argumentation units
Argumentation units are introduced at grade 3 and provide students with regular opportunities to explore and discuss available evidence, time and support to consider how evidence may be leveraged in support of claims, and independence that increases as they mount written arguments in support of their claims.
Launch units
Launch units are the first units taught in each year of Amplify Science. The goal of the Launch unit is to introduce students to norms, routines, and practices that will be built on throughout the year, including argumentation, active reading, and using the program’s technology. For example, rather than taking the time to explain the process of active reading in every unit in a given year, it is explained thoroughly in the Launch unit, thereby preparing students to read actively in all subsequent units.
Core units
Core units establish the context of the unit by introducing students to a real-world problem. As students move through lessons in a Core unit, they figure out the unit’s anchoring phenomenon, gain an understanding of the unit’s disciplinary core ideas and science and engineering practices, and make linkages across topics through the crosscutting concepts. Each Core unit culminates with a Science Seminar and final writing activity.
Engineering Internship units
Engineering Internship units invite students to design solutions for real-world problems as interns for a fictional company called Futura. Students figure out how to help those in need, from tsunami victims in Sri Lanka to premature babies, through the application of engineering practices. In the process, they apply and deepen their learning from Core units.
Idaho Science Standards Alignment
Amplify Science was built from the ground up to fully embrace the instructional shifts outlined in A Framework for K-12 Science Education (2012), the same framework on which Idaho Science Content Standards were founded. Most grade levels’ respective set of Amplify Science units therefore fully address the necessary Idaho Science Content Standards (see correlation). Grade 1 teachers should plan to also use the companion mini-lesson provided below to achieve full standards coverage for their grade.
Grade 1 Companion
Standard: 1-LS-1.3 Use classification supported by evidence to differentiate between living and non-living things.
Recommended placement: Following Lesson 1.1 of the Animal and Plant Defenses unit.
Resources: Classroom Slides
Science (Middle School Physical Science) Evaluation Form
Science (Middle School Life Science) Evaluation Form
Science Evaluation Form Middle School Earth and Space Science
Needs of Plants and Animals
Domains: Life Science, Earth and Space Science, Engineering Design
Unit type: Investigation
Student role: Scientists
Phenomenon: There are no monarch caterpillars in the Mariposa Grove community garden since vegetables were planted.
Pushes and Pulls
Domains: Physical Science, Engineering Design
Unit type: Engineering design
Student role: Pinball engineers
Phenomenon: Pinball machines allow people to control the direction and strength of forces on a ball.
Sunlight and Weather
Domains: Earth and Space Science, Life Science, Engineering Design
Unit type: Modeling
Student role: Weather scientists
Phenomenon: Students at Carver Elementary School are too cold during morning recess, while students at Woodland Elementary School are too hot during afternoon recess.
Animal and Plant Defenses
Domain: Life Science
Unit type: Modeling
Student role: Marine scientists
Phenomenon: Spruce the Sea Turtle lives in an aquarium and will soon be released back into the ocean, where she will survive despite ocean predators.
Light and Sound
Domains: Physical Science, Engineering Design
Unit type: Engineering design
Student role: Light and sound engineers
Phenomenon: A puppet show company uses light and sound to depict realistic scenes in puppet shows.
Spinning Earth
Domain: Earth and Space Science
Unit type: Investigation
Student role: Sky scientists
Phenomenon: The sky looks different to Sai and his grandma when they talk on the phone.
Plant and Animal Relationships
Domains: Life Science, Engineering Design
Unit type: Investigation
Student role: Plant scientists
Phenomenon: No new chalta trees are growing in the fictional Bengal Tiger Reserve in India.
Properties of Materials
Domains: Physical Science, Engineering Design
Unit type: Engineering design
Student role: Glue engineers
Phenomenon: Different glue recipes result in glues that have different properties.
Changing Landforms
Domain: Earth and Space Science
Unit type: Modeling
Student role: Geologists
Phenomenon: The cliff that Oceanside Recreation Center is situated on appears to be receding over time.
Balancing Forces
Domain: Physical Science
Unit type: Modeling
Student role: Engineers
Phenomenon: The town of Faraday is getting a new train that floats above its tracks.
Inheritance and Traits
strong>Domain: Life Science
Unit type: Investigation
Student role: Wildlife biologists
Phenomenon: An adopted wolf in Graystone National Park (“Wolf 44”) has some traits that appear similar to one wolf pack in the park and other traits that appear to be similar to a different wolf pack.
Environments and Survival
Domains: Life Science, Engineering Design
Unit type: Engineering design
Student role: Biomimicry engineers
Phenomenon: Over the last 10 years, a population of grove snails has changed: The number of grove snails with yellow shells has decreased, while the number of snails with banded shells has increased.
Weather and Climate
Domains: Earth and Space Science, Engineering Design
Unit type: Argumentation
Student role: Meteorologists
Phenomenon: Three different islands, each a contender for becoming an Orangutan reserve, experience different weather patterns.
Energy Conversions
Domains: Physical Science, Earth and Space Science, Engineering Design
Unit type: Engineering design
Student role: System engineers
Phenomenon: The fictional town of Ergstown experiences frequent blackouts.
Vision and Light
Domain: Physical Science, Life Science, Engineering Design
Unit type: Investigation
Student role: Conservation biologists
Phenomenon: The population of Tokay geckos in a rain forest in the Philippines has decreased since the installation of new highway lights.
Waves, Energy, and Information
Domains: Physical Science, Life Science, Earth and Space Science, Engineering Design
Unit type: Modeling
Student role: Marine scientists
Phenomenon: Mother dolphins in the fictional Blue Bay National Park seem to be communicating with their calves when they are separated at a distance underwater.
Patterns of Earth and Sky
Domains: Physical Science, Earth and Space Science
Unit type: Investigation
Student role: Astronomers
Phenomenon: An ancient artifact depicts what we see in the sky at different times — the sun during the daytime and different stars during the nighttime — but it is missing a piece.
Earth’s Features
Domain: Earth and Space Science
Unit type: Argumentation
Student role: Geologists
Phenomenon: A mysterious fossil is discovered in a canyon within the fictional Desert Rocks National Park.
Modeling Matter
Domain: Physical Science
Unit type: Modeling
Student role: Food scientists
Phenomenon: Chromatography is a process for separating mixtures. Some solids dissolve in a salad dressing while others do not. Oil and vinegar appear to separate when mixed in a salad dressing.
The Earth System
Domains: Earth and Space Science, Physical Science, Engineering Design
Unit type: Engineering Design
Student role: Water resource engineers
Phenomenon: East Ferris, a city on one side of the fictional Ferris Island, is experiencing a water shortage, while West Ferris is not.
Ecosystem Restoration
Domains:Physical Science, Life Science, Earth and Space Science, Engineering Design
Unit type: Argumentation
Student role: Ecologists
Phenomenon: The jaguars, sloths, and cecropia trees in a reforested section of a Costa Rican rain forest are not growing and thriving.
Geology on Mars
Domain: Earth and Space Science
Unit type: Launch
Student role: Planetary geologists
Phenomenon: Analyzing data about landforms on Mars can provide evidence that Mars may have once been habitable.
Earth, Moon, and Sun
Domains: Earth and Space Science, Physical Science
Unit type: Core
Student role: Astronomers
Phenomenon: An astrophotographer can only take pictures of specific features on the Moon at certain times.
Thermal Energy
Domain: Physical Science
Unit type: Core
Student role: Thermal scientists
Phenomenon: One of two proposed heating systems for Riverdale School will best heat the school.
Ocean, Atmosphere, and Climate
Domains: Earth and Space Science, Physical Science
Unit type: Core
Student role: Climatologists
Phenomenon: During El Niño years, the air temperature in Christchurch, New Zealand is cooler than usual.
Weather Patterns
Domains: Earth and Space Science, Physical Science
Unit type: Core
Student role: Forensic meteorologists
Phenomenon: In recent years, rainstorms in Galetown have been unusually severe.
Populations and Resources
Domains: Life Science, Earth and Space Science
Unit type: Core
Student role: Biologists
Phenomenon: The size of the moon jelly population in Glacier Sea has increased.
Matter and Energy in Ecosystems
Domains: Life Science, Earth and Space Science, Physical Science
Unit type: Core
Student role: Ecologists
Phenomenon: The biodome ecosystem has collapsed.
Traits and Reproduction
Domain: Life Science
Unit type: Core
Student role: Biomedical students
Phenomenon: Darwin’s bark spider offspring have different silk flexibility traits, even though they have the same parents.
Microbiome
Domain: Life Science
Unit type: Launch
Student role: Microbiological researchers
Phenomenon: The presence of 100 trillion microorganisms living on and in the human body may keep the body healthy.
Metabolism
Domain: Life Science
Unit type: Core
Student role: Medical researchers
Phenomenon: Elisa, a young patient, feels tired all the time.
Force and Motion
Domain: Physical Science
Unit type: Core
Student role: Physicists
Phenomenon: The asteroid sample-collecting pod failed to dock at the space station as planned.
Force and Motion Engineering Internship
Domains: Engineering Design, Physical Science
Unit type: Engineering internship
Student role: Mechanical engineering interns
Phenomenon: Designing emergency supply delivery pods with different structures can maintain the integrity of the supply pods and their contents.
Plate Motion
Domain: Earth and Space Science
Unit type: Core
Student role: Geologists
Phenomenon: Mesosaurus fossils have been found on continents separated by thousands of kilometers of ocean, even though the Mesosaurus species once lived all together.
Rock Transformations
Domain: Earth and Space Science
Unit type: Core
Student role: Geologists
Phenomenon: Rock samples from the Great Plains and from the Rocky Mountains — regions hundreds of miles apart — look very different, but have surprisingly similar mineral compositions.
Natural Selection
Domains: Life Science, Earth and Space Science
Unit type: Core
Student role: Biologists
Phenomenon: The newt population in Oregon State Park has become more poisonous over time.
Evolutionary History
Domains: Life Science, Earth and Space Science
Unit type: Core
Student role: Paleontologists
Phenomenon: A mystery fossil at the Natural History Museum has similarities with both wolves and whales.
Harnessing Human Energy
Domains: Physical Science, Earth and Space Science, Engineering Design
Unit type: Launch
Student role: Energy scientists
Phenomenon: Rescue workers can use their own human kinetic energy to power the electrical devices they use during rescue missions.
Phase Change
Domains: Physical Science, Earth and Space Science
Unit type: Core
Student role: Chemists
Phenomenon: A methane lake on Titan no longer appears in images taken by a space probe two years apart.
Phase Change Engineering Internship
Domains: Engineering Design, Physical Science
Unit type: Engineering internship
Student role: Chemical engineering interns
Phenomenon: Designing portable baby incubators with different combinations of phase change materials can keep babies at a healthy temperature.
Chemical Reactions
Domains: Physical Science, Life Science, Earth and Space Science
Unit type: Core
Student role: Forensic chemists
Phenomenon: A mysterious brown substance has been detected in the tap water of Westfield.
Magnetic Fields
Domain: Physical Science
Unit type: Core
Student role: Physicists
Phenomenon: During a test launch, a spacecraft traveled much faster than expected.
Light Waves
Domains: Physical Science, Life Science, Earth and Space Science
Unit type: Core
Student role: Spectroscopists
Phenomenon: The rate of skin cancer is higher in Australia than in other parts of the world.
Earth’s Changing Climate
Domains: Earth and Space Science, Life Science
Unit type: Core
Student role: Climatologists
Phenomenon: The ice on Earth’s surface is melting.
Earth’s Changing Climate Engineering Internship
Domains: Earth and Space Science, Engineering Design
Unit type: Engineering internship
Student role: Civil engineers
Phenomenon: Designing rooftops with different modifications can reduce a city’s impact on climate change.
Access program
In addition to the grade-level sample boxes that we provided, we’ve also created custom demo accounts just for Idaho reviewers.
To access the digital portion of the program, click the link below, select “Log In with Amplify,” and then refer to the Start here digital access flyer for your personalized login credentials.
Tutorial videos
Check out these videos for support on how to navigate the Amplify Science curriculum website, teacher’s guide, materials kits, and more!
Resources
S1-02: Community and joy within K–8 science instruction: Desiré Whitmore
In this episode, we join Eric Cross as he sits down with physicist and science education specialist, Desiré Whitmore. Listen in as Desiré explains her work at the Exploratorium, a public learning laboratory. Eric and Desiré discuss finding passion in science, the importance of meeting students we’re they’re at, and K–8 science instruction with real-life connections. Desiré chats with Eric about her work on supporting the science of teaching science content at the Exploratorium museum.
Explore more from Science Connections by visiting our main page.
Desiré Whitmore (00:00):
I think it’s really amazing when we can realize as teachers, like, no, our job is not to just enforce rules on our students, right? Our job is to help students to achieve more learning.
Eric Cross (00:37):
Welcome to Science Connections. I’m your host, Eric Cross. My guest today is Desiré Whitmore. Desiré has held positions as a science curriculum specialist with Amplify Science, a professor of laser and photonics technology at Irvine Valley College, and is now the senior physics educator in the Teacher Institute at the Exploratorium in San Francisco. Her current work is focused on providing support and professional development to middle and high school science teachers to help them teach through inquiry. In this episode, we discussed Desiré’s pathway into physics, the impact of educators in her life, and the importance of representation for students in the classroom. I’m so excited for you to meet my physicist friend, Dr. Desiré Whitmore. All right. So just like a superhero, STEM superhero, you have an origin story and so—
Desiré Whitmore (01:36):
How long is this podcast gonna be? ‘Cause, you know, I can talk for days, so you—
Eric Cross (01:40):
I know, I know! But it’s, it’s…so, OK. We can give us a highlight. So, you know, 30 minutes. But what would be the origin story? You can start from any point in time, but what’s that journey like?
Desiré Whitmore (01:51):
I’m gonna start at the beginning, when I was really young, just because I think it’s important. Neither of my parents were college-educated. My mother didn’t finish high school. My father went back and got a GED later. But my father’s grandmother, her name was Claudia Pairs, and she was a teacher, right? So when I was a kid, she actually kind of raised me from, I don’t know, until I was around seven or eight. And so she was very important in who I became, I think because she taught me that college is important and she taught me to think. She taught me to ask questions. She taught me how to ask questions. Just the Exploratorium likes to do. Which is why I fit so well here. She taught me to always wonder and always think about things. And I remember as a kid, she taught me to count and read and write when I was, like, three. And she would always have bubbles at her house. And I was obsessed with bubbles. I thought bubbles were the coolest thing in the world. And just how you can take your breath and create this thing that now you can see, and it’s your breath, right? It’s your breath inside of a bubble and it’s flying around and it has all these cool colors, and then it would fly up and then eventually just pop. And you’re like, where did it go? Now my breath is just up there. Not understanding, as a kid, but my breath is always everywhere. I didn’t understand any of that, but I understood that my breath was inside of a bubble. That’s my earliest memory of thinking about science, was from that. And she was not a science teacher. She was—I don’t even know what she taught. I think she was an elementary school teacher, maybe. She died when I was 12. So I don’t have super-strong memories or of understanding who she was, only that she raised me and what she taught me as a kid. But that in itself really helped me because then when I was in the environment that I was in at home with my parents, which was not at all the environment she provided for me, I always had the things she taught me in my head, right? So I was always asking questions. My mother hated it. I was always taking things apart and putting them back together. So I used to take apart TVs and VCRs and vacuum cleaners and telephones, and my mother’s like, “Oh my God, I’m gonna murder you.” And she tried a couple times, too.
Eric Cross (04:25):
Did you ever put ’em back together and realize you had extra parts? You’re like, oh, hi.
Desiré Whitmore (04:29):
Oh yeah. All the time. Yeah. Yeah. VCRs have a lot of extra pieces. You’re like, “What do you even…it still works. It’s fine.” <laugh> You know? And vacuum cleaners too. They had a lot of extra parts, <laugh> all the time. And TVs. I should not have been playing with TVs. But like I said, I didn’t have a lot of parental, guidance as a child. So, like, whatever—I’m opening up TVs.
Eric Cross (04:54):
There’s a lot of open inquiry going on in your household. Yeah. Unsupervised.
Desiré Whitmore (04:59):
Unsupervised. But I didn’t know what it was or what it meant as a kid. I mean, I used to put things in the microwave. I did so many microwave experiments as a child, trying to cook different foods or melt different things. And so I think those kinds of experiences, where I was allowed to just be curious, kind of shaped who I am today. And then I kind of got into…you know, when I was in school, I loved math. In 10th grade, I had my first Black teacher, he was my chemistry teacher. His name was Mr. Strickland. And I was like, chemistry is cool, dude. And he was not the best teacher, but he was fun. Like you were saying, he was me, and he was talking to us the way I speak. And he was so like, just kind of chill and happy-go-lucky, I guess. But he wasn’t…he hadn’t taught chemistry in a long time. So he wasn’t a very good teacher. And me and one other kid in the class were in love with chemistry. And so we would read the book and do all the homework and he’d be in class lecturing and we’re like, “That’s not right, Mr. Strickland, like, what are you talking about?” And then he’d be like, “Oh, really, Desiré? Do you wanna teach the class, then?” And I’d be like, “Yeah.” And so I would go up and I would teach my chemistry class in high school, because the teacher was trying to make an example out of me. But he was also, I think, willing to be like, “I really don’t know.” And I really appreciated that. That he wasn’t just like, “I know all of the answers and you’re wrong.” Like, he wasn’t being a jerk, right? Like, the fact that I said, “Yes, I do wanna teach it,” and he actually let me do it? That’s pretty dope. And then I liked physics in my senior year in high school, but I didn’t think it was where I was gonna go or anything. I loved music and I loved math. Those were my two subjects.
Eric Cross (06:51):
What was it about math that resonated with you?
Desiré Whitmore (06:55):
I think it helped me understand the world a lot better. I didn’t have strong science teachers, I guess, growing up. It was a lot of reading out of books or watching laser discs in class. That’s how old I am.
Eric Cross (07:12):
Laser discs.
Desiré Whitmore (07:13):
Laser discs. And you know, so there wasn’t a lot of…I moved around a lot as a kid. I didn’t have this straight curriculum. You know, in one year, in the third grade, I went to three different schools.
Eric Cross (07:25):
Mm. Oh wow.
Desiré Whitmore (07:26):
It was kinda hard for me to latch onto school. But with math, because I could look at math and actually understand the world in it, I could see how math can be used to describe how things work.
Eric Cross (07:40):
I almost imagine, especially with so much transition in your life, it helped make sense of things. You had a lot of transition going on, but you were able to understand the world through the process of math. And then this early exposure, it kind of reminds me my own story too. Because there were these books that would do these cross sections of a cruise ship or a machine; that’s what got me really into engineering. Kind of How Stuff Works. I would watch that on Nova, How Stuff Works. I’d always be fascinated. Even Sesame Street had a segment where they would show you crayons and how the dye was added. You remember that?
Desiré Whitmore (08:19):
Yep. Yeah.
Eric Cross (08:20):
Young Desiré, doing photronics…photronics?
Desiré Whitmore (08:24):
Photonics.
Eric Cross (08:24):
Photonics. Photonics at home with the microwave and all these other things.
Desiré Whitmore (08:29):
Sure. How ’bout that.
Eric Cross (08:30):
<laugh> Right. And then loving math. So, early, I could see this combination, sort of this alchemy, happening inside you. And then, how did that lead to you becoming a physicist?
Desiré Whitmore (08:46):
It’s not as straightforward as it seems it should be. It’s obvious to everyone. <laugh>. But it wasn’t obvious to me. ‘Cause I wanted to be a lawyer. You know, because my parents weren’t educated, they didn’t really know…both of my parents and their subsequent spouses when they broke up—so my parents and my stepparents—are all bus drivers. And so they don’t know what options are. Right? So for them it’s like, “You have to be—you can be a doctor. You can be a lawyer. ‘Cause you’re smart. I know you’re smart, so you’re gonna be one of those things.” And I was like, “I don’t wanna be a doctor. That’s not actually interesting to me.” I did wanna be a teacher when I was younger, because I knew that my grandmother was one. But yeah, I went in and I was like, “I’m gonna be a lawyer. I’m gonna be a lawyer.” And then I go to college and I was like, ‘Eh, I don’t. I hate writing.” <Laugh> Like, I love reading, but I don’t writing. So I don’t think I wanna be a lawyer. I love music and I love math. I was originally going to major in music and math, but then I went to community college because I missed my opportunity to go to university for…long story. And so I’m at community college and I was like, “You know what? I’m gonna just do something new. I’m gonna be a marine biologist.” So my major was marine biology, and then they’re helping me pick out my classes. And they had zero math there. And I was like, “Pardon me. I think there’s a mistake, but I’m not taking any math.” And they were like, “No, you’re done with all your math. For marine biology, you only need calculus. And you took all of that in high school, so you’re done.” And I was like, “No, this is not gonna work for me, dude.” So I continued taking calculus anyway and moving on in math. And then I realized that biology wasn’t what I needed, but I did love my chemistry and I loved my physics classes. So I asked those teachers—chemistry, physics, and math teachers in community college, my professors—”I don’t wanna be a marine biologist and I don’t wanna be a lawyer. What do I do? What do you think I could study? I really like chemistry and math and physics.” And so all of them, all three of these professors told me, “Oh, it sounds chemical engineering would be good for you, so you should be a chemical engineer.” And I was like, “OK, cool. No problem.” That’s what I did. So I got my degree in chemical engineering. Right. And I finished community college, studying chemical engineering. I was like, “This is really cool. This is a lot of fun. I love engineering.” And then I transferred to UCLA as a chemical engineering major. And I was like, “I hate this.” <Laugh>. “I hate it a lot.” It was just…
Eric Cross (11:07):
What was it about chemical engineering that you were just not feeling anymore? What was it that just made you go, “nope”?
Desiré Whitmore (11:12):
It didn’t—at least the way it was taught to me—it wasn’t as as…exploratory, I guess. There wasn’t a lot of theory in it. There was just a lot of “OK, pull out a ruler and you’re gonna draw a thing and then this is how you’re gonna build a reactor.” And it didn’t seem very scientific to me. The science was missing. And don’t get me wrong, I understand, now that I have a degree in chemical engineering, that it’s not that chemical engineering is not scientific. But it’s that you build up the science and then you don’t focus on it. You focus on the engineering aspect of it. Which is, you have the science and the scientists will work on that aspect. But then how can WE do kind of larger batch chemistry. And for me, that was just less interesting. It was a lot of pushing buttons and just plug-and-play equations stuff. Instead of diving into first principles of why things happen in chemical engineering. There was no “why things happen”; it was “this is what happens, so this is the next step.”
Eric Cross (12:25):
You had to go so far into your academic career to realize that this is what chemical engineering is. And we were talking about representation, and not having examples or parents; your families were bus drivers. My mom was a receptionist and executive assistant, things like that. And I was the first of many, like you…we kind of had to go through and invest all this time and money to finally get to this place to realize, “This ain’t it.”
Desiré Whitmore (12:58):
This is not for me, yeah.
Eric Cross (12:59):
This is not for me. That was a long journey to get to that point.
Desiré Whitmore (13:03):
It was. Especially because I went through community college and I took a long time in community college, ’cause I was working full-time. So I was working full-time, going to community college. Took me a while. And then I finally get to UCLA. I’m like, “Yeah, I’m finally gonna get my degree and go make money!” And then I was like, “Ooh, no.” I mean, I could go and make money, don’t get me wrong. I could have graduated and made a ton of money. But I was not happy at all and I did not enjoy what I was doing. So, while I was in undergrad, I realized I don’t wanna do chemical engineering anymore. But what do I wanna do? But then I was taking…I took a quantum mechanics class. And that class blew my whole mind. And I was like, “This is the coolest thing that I’ve ever learned in my life, and this is what I wanna do.” And so I went and talked to my professor and I was like, “Can I work for you? Can I do research? Because this is amazing and I wanna do this.” I felt it was too late for me. I had been in school for so long and I was already kind of burnt out. So I was, “I’m not going to change my major. That’s just outta the question for me right now. It costs so much money for this degree and I don’t have—I’m not just gonna waste my time and keep working all these jobs.” So I had three jobs in college. And it was like, I worked at Radio Shack, I did research for this professor, and I worked in the library, the chemistry and physics library.
Eric Cross (14:28):
I love the fact that we’ve talked about laser discs; you said Radio Shack; and we talked about the analog internet of the encyclopedia salespeople. And I know all of those things. And I’ve been through all of those things together.
Desiré Whitmore (14:43):
Just in case people don’t know how old I am. <Laugh>
Eric Cross (14:47):
For our listeners who are way younger, yeah, this is how we grew up. This is how we—these things are extinct now. There’s this element of this kind of cultural connection. I think that we experience that. It kind of it flies under the radar. People don’t really realize it until you’re in an environment that’s different from what you’re used to. And you realize that, “Oh wow. this is not what I’m used to.” And the things that I’m finding funnier, the things that I connect with, it’s not what everybody else connects with. And as a teacher, it’s the same thing, right? Like, we go in the classroom and you know, you and I are rapping about laser discs and Radio Shack and I’m trying to talk to my kids about it. And they’re like, “Yo, Cross, what is that? Are you gonna give us a history lesson? What are these things?”
Desiré Whitmore (15:35):
Yeah.
Eric Cross (15:36):
And I found myself having to stay connected to pop culture, because I teach 12- and 13-year-olds all day. And it’s great for keeping things relevant for my students. But when I talk to my friends that are my peers, they’re like, unless they’re a teacher, they’re like, “I got no idea what you’re talking about.”
Desiré Whitmore (15:55):
Yeah. I have a friend who’s also a middle-school teacher and she’s always coming to me with all this. I’m like, “What are you talking about?” She did the Glow-up Challenge, but she did the Glow-down Challenge. So she invented a new thing. She’s like, “No, I couldn’t do Glow Up ’cause that’s too much. So I did the Glow-Down Challenge.” And it’s the cutest thing ever. And the students think it’s amazing. And I’m like, “That’s awesome. But I have no idea what the point of that is.” <Laugh>
Eric Cross (16:21):
And there’s this theme, too, that when we talk about teaching kids STEM, there’s this soft part of it, this relational piece of it that you mentioned, of this connective aspect that in a certain way kind of even superseded the content knowledge that your teacher even had at that point, where you’re going up and teaching the class. But just the fact that someone looked like you or spoke like you or connected with you in a certain way made a big difference to who you are as…well, the trajectory of where you went.
Desiré Whitmore (16:57):
Yeah.
Eric Cross (16:57):
“I like chemistry. It resonates with me.” And it’s something I think can get lost. And I think just to kind of a good segue, I use Amplify my classroom, and one of the reasons why is because of the representation that is in these videos. And you were part of crafting this for…was it the fifth grade?
Desiré Whitmore (17:21):
I mean, it was K–8. So I was—
Eric Cross (17:23):
OK, so you were doing the whole thing.
Desiré Whitmore (17:24):
Yeah, I was a part of the K–8 science team. My title was science curriculum specialist. But in reality I was hired to do the engineering internships, mostly. Which are middle school. And to be a sim developer. So sims K–8. I worked on several of them in both middle school and elementary. Yeah.
Eric Cross (17:47):
What was that like for you? When you were designing curriculum? ‘Cause as a teacher, it’s, you know, I think with teachers it’s kind of…I would consider myself, if I was gonna use hip hop as a metaphor, I’m more of a DJ than an MC. Where I wanna remix things that exist, versus, I don’t wanna write the lyrics in freestyle. So I don’t want to go and write the curriculum completely; I wanna take something that’s solid and then I want to go ahead and remix it. You are great at both. What was the process for you, being on that team, designing? How did you go about making, “OK, we’re gonna create this experience for kids”?
Desiré Whitmore (18:25):
It was, it was amazing. I learned so much, so much. It was the best job I had before I came to the Exploratorium. The process was amazing, because it wasn’t just me, right? It wasn’t just me. It was a whole team. And each unit had its own team. So we had a scientist, which I was the scientist we had. So we had a scientist; we had a literacy specialist, because it was really important to increase science literacy so that students understand not just that science exists, but “What are the terms that are used in science and how can I speak and act a scientist? What are the things that scientists actually do in their real life?” Then we had an assessment specialist and then we had a simulation specialist. And so, on the units that I was on, sometimes I was both the sim developer and the scientist, or sometimes I was just the sim developer and I got to work alongside another scientist, which was always fun. And so it was really nice, because I was working alongside master teachers. People who had been teaching for years, and they were able to help me better understand. ‘Cause I’ll come in and I’ll be like, “Yeah, there’s a unit on light waves, let’s come in and teach this unit on light waves!” <laugh> I was the sim developer and scientist on that unit, and there was another scientist working on the unit, but they were like, “Well, Desiré literally builds lasers, so I think she should be the science developer.” So we kinda had two science developers on that one, which was fun. But I come in and she’ll come in and she’ll be like, “Yeah, I think this is where we wanna go and this is what we wanna teach.” I’m like, “No way! Like, that’s not accurate, right?” And so I can come in, but then I’m coming in with all this crazy lingo, right? I’m up here. But then also I have taught kids about lasers and optics and photonics my whole career. So I’m also very capable of bringing it down to where kids need it to be. What I don’t know is how effective that is, right? When to do it and when not to do it. When to bring the level up; when to bring the level down. And so working alongside these other teachers and assessors really helped me to do that. And so for me it was just two years of deep learning experience. I learned—every single day at work, I learned something new. Which is something that I value and I’ve wanted in my career, my whole life. We made active decisions in that room. Like, “We want to interview scientists who are scientists of color or who have different abilities or who have different representations in all kinds of ways.” Right? And then we also have these fake internships, or not even the internships, but just in the general units. And we actively wrote scripts for those. And we actively wrote in those scripts, like, “This is a Black woman. This is an Indian woman. This is a Jewish man in a wheelchair.” Like, we specifically dictated exactly who we wanted in these videos, because we knew that representation was super-important and we knew that we wanted students to be able to connect.
Eric Cross (21:35):
Right. One of the things, I appreciate what I’m hearing a lot in that is the amount of intentionality that went into this. But even now as you’re reliving it, you’re still almost iterating on how could we improve it or how can we make it different or reach more people. And I think that goes towards when we’re talking about including more people and inclusion. Like, it’s not a binary thing. You’re always modifying; you’re always iterating; you’re always redesigning and improving to be more inclusive, to reach more students. Because you know, to your point, part of it is, “Yes, we wanna do this really awesome science curriculum,” but the other part of it is there’s more to it than just your content. And I think now more than ever…I use—we just finished the food bar unit. Metabolism. And in there there’s a simulator. They always ask me when I show the videos, “Are these, are these real people? Are these real situations?” And I tell ’em, “Well, the story is real, but these are all fictional actors. But what’s actually happening happens. It’s real.” And they get really into it. And I think one of the other things is with your simulations—especially the engineering units—there’s no one right answer. And so my students who want to go, “Mr. Cross, I wanna make the best bar! Perfect 10, best taste, cheapest!” And I’m like, “All right, good luck!”
Desiré Whitmore (23:06):
Yeah. Go do that.
Eric Cross (23:09):
Casue there’s something called trade-offs! It could happen! And they’re like, they’re trying. They get into the code. They try to open up the Inspect Element, when they feel like hackers.
Desiré Whitmore (23:17):
Yeah, they do. But these kids like, they’re so smart and they’re so resourceful. And I’m just thinking like, maybe that’s how we challenge them more, right? Sometimes we can give them these kinds of things where it’s like, “Go and create a program, ’cause that’s the level you’re at <laugh>. Go and create this program to do something similar that’s related to the work that we’re doing.”
Eric Cross (23:38):
I’ve had some of my own students redesign—I have one student who redesigns every assessment I give him. I give the project; I give the options for the final goal; and he always chooses—if I give three options, he always chooses option four. If I choose two options, he’s choosing option three. And so he’ll go into Google Sheets, he’ll pull all the data and then he’ll construct his own kind of spreadsheet with all the probabilities of different things.
Desiré Whitmore (24:06):
You tell this kid to make a GitHub right now <laugh> so that he can get a job as soon as he’s done with high school. <laugh>.
Eric Cross (24:12):
He’s amazing. And we did this one project where students had to design a Netflix show to show their understanding of metabolism. And they had to do four episodes. So I gave him a template. It’s not from me; it’s from, I think, EdTechPicks.org or something. And it looks like the whole Netflix splash page. They took photos, did the whole deal. He created NOTflix. Everyone else did Google Slides. His Google Slides was interactive. So when you clicked on different boxes, it actually took you to the next splash page of that show. I mean, it was….
Desiré Whitmore (24:48):
That’s fantastic.
Eric Cross (24:49):
It was, it was. I recorded his presentation. It was brilliant.
Desiré Whitmore (24:53):
But that’s amazing. And that speaks to your strengths as a teacher and why you’re an amazing teacher. Because you see the students and what they’re trying to do and you work with them; you meet them where they are. Right? There are so many teachers who would just be frustrated with that student. And it’d be like, “No, these are not your options. Your option was to do what I told you to do.” And there are many teachers who would do that. And I think it’s really amazing when we can realize as teachers, “No, our job is not to just enforce rules on our students. I mean, that is part of the job, because that’s what school was when it was created. But our job is to help students to achieve more learning in what we’re trying to do. And so the fact that you are so good with this student and that you encourage him to go above and beyond when he can, I think it’s so amazing.
Eric Cross (25:49):
Well, that brings me to my favorite group, organization, and the phase of your career of where you are now: The Exploratorium. And I wanted to kind of rap, talking about what you do now. Because the Exploratorium—I tell people, they go, what is that place? And maybe you can tell us what it is and then what you do. But for me, I’ll just tell everybody: It’s Disneyland for science teachers. And I love going there. I not only love going there because of what I receive from it professionally. Many of the PDs, I don’t even call ’em PDs—just communal learning experiences, that I’ve had that have been led by you and Lori and, and Tammy and the rest, and everybody that’s there have been incredible. And I have so much fun. Emotionally, I get excited when I go. When I’m on the plane, I’m like, “Here we go!” And then we go and we’re making fudge or we’re blowing darts with marshmallows across the room in the theme of Boba Fett. There’s just these rad things that are going on there. And it’s not like anything I’ve ever experienced before. So maybe we can close with talking about what the Exploratorium is, what you do there, for people who’ve never been and have been a part of it.
Desiré Whitmore (27:19):
I’m gonna give you what my definition of the Exploratorium is.
Eric Cross (27:21):
That’s what we want.
Desiré Whitmore (27:22):
So, the actual definition is, we are a public learning laboratory. We are known as the Museum of Art, Science and Human Perception. Cool. But, like, what does that all mean? Right? And I think your description of the Disneyland for science teachers, I think that’s a perfect description. ‘Cause for me, I tell people like, “Oh, I wanna go to the happiest place on earth.” And for me, that is the Exploratorium. And yes, I work there, and yes, it’s still true for me. So the Exploratorium is this huge museum. It’s an interactive science museum. And art—we have a lot of art. And it’s all about learning through doing. It’s not about learning science by going up to an exhibit and reading the little paper next to it. It’s like, no, you go up to an exhibit and you interact with it and you teach yourself science. The goal of the Exploratorium is really to help people understand that learning science, doing science, isn’t reserved for only scientists. Doing science is something that everyone in the world should and does do. And so helping people understand that everything we do is science is kind of the point of the Exploratorium to me.
Eric Cross (28:35):
Even the building itself…one of the other cool things too is, for people that don’t know, it’s the size of Costco or two.
Desiré Whitmore (28:43):
Yeah. Yeah.
Eric Cross (28:44):
It’s immense! And even the building itself teaches. Like, you have that whole workshop, dead-center in the middle of the floor where they’re designing things. It’s like inside-out. And then I remember going to the one experience where I think it was Eric who showed us that it’s one of the few facilities that is actually cooled by the Bay water. And there’s only a couple of those in the state that can do that. And it has a platinum rating, something wild that. So even just the building itself…everything that if they can extract every ounce of science teaching in that, it’s in there. And you are in a very important program for me. And can you talk a little bit about maybe what you’re doing in T.I.?
Desiré Whitmore (29:33):
So I am in the Teacher Institute. I’m a physicist in the Teacher Institute. And the Teacher Institute is a group of teachers and scientists. And our job is to basically support middle school and high school science teachers and teacher leaders in the state of California, but science teachers around the world, in their pursuit of science teaching. And by support, I mean we provide professional development. We provide other things, communities of practice, and we go and do workshops in certain places. We go to India to teach Tibetan monks and nuns science. And we go to Costa Rica to teach teachers all over the country of Costa Rica about science. And so our job is really, to help science teachers feel more secure in their science teaching and help to retain them in the field, because a good science teacher is so important in helping our students thrive. And so our job—and we take this very seriously—is to help science teachers thrive. And we are made up of PhD scientists and veteran classroom teachers. So we have on the one side teachers who have been teaching middle school or high school for years. One of my coworkers, Zeke, who I work with the most, he was a high school physics and environmental science teacher for 21 years before coming to the Exploratorium. And then me, I was never a classroom teacher. I was a professor; I was a physics professor at a community college, and I was a researcher. So my deep knowledge of physics and current knowledge of physics—or knowledge of current physics—combined with Zeke’s extremely experienced pedagogy is really how we work together as a team. And it’s not just Zeke, right? We’ve got a geologist on the team, Eric Muller. We’ve got Tammy, who’s a middle-school bio teacher. We’ve got, Julie Yu, who is a chemical engineer, PhD, and also a prior middle school teacher, former middle school teacher. We’ve got Hilleary Osheroff, who was a PhD biologist who used to work at the American Museum of Natural History. We’ve got Lori Lambertson, who was a middle-school math teacher. And so, you know, we all come together to bring our experiences both in and out of the classroom and in and out of the research lab to provide teachers with the best inquiry-driven stuff we can. And we’re very—we’re so equity-focused, because we believe that that’s important, right? We know that the impact of our work is, I think, why most of us are here. It’s why I’m here. In undergrad, my grad school, and my postdoc, I would go into classrooms. I would go into science museums and teach science to people. And I probably reached out to maybe…over that whole time, I would say a couple thousand people, right? Maybe a couple thousand people total. That’s great. But over 15 years of reaching out and only reaching a couple thousand people, that’s rough, right? And now I’m at the Exploratorium, and I know that if I reach one teacher, right? If I can teach one teacher…let’s say you. How many students do you have in your classes a year?
Eric Cross (33:11):
Two hundred a year.
Desiré Whitmore (33:12):
You have 200 students a year that you teach. So if you teach for 10 years, that’s 2000. That’s 2000 students. So I have, by teaching you today, assuming that I’m actually teaching you something that’s gonna be useful for you—
Eric Cross (33:29):
You do! And you are!
Desiré Whitmore (33:30):
You are going to be impacting these 2000 students over the next 10 years. And of course you’re gonna be in teaching for much longer than that. But let’s just say in 10 years, that payoff is so much higher, right? And you’re one teacher. But I have 30 of you in my workshop! And so if all of these 30 teachers each teach 2000 kids over the next 10 years, then I’m actually doing something. I’m actually changing the way that students see science, through changing the way that you see science. Right? And so I take my job very seriously, as we all do. Like, we’re so invested in our teachers. And it’s not that we don’t care about students, ’cause we absolutely do. But we understand that without good teachers, students aren’t going to be able to thrive, as often as they would otherwise. I was able to do it somehow. But I’m one. There are so many other kids who could have gone into science who didn’t because they felt they never connected to it. So our job is to try to help teachers connect to it. And an important part of that is allowing you all to experience science as a learner. We want you to play and have joyful experiences. We want you to enjoy science and to try to think about it from the perspective of your students. Walk in their shoes. So that when you then go back to your classroom, you are able to think about like, “Oh yeah, you know, my students totally asked the same question that I asked, or that another teacher asked in the workshop because they had the foresight to think about that’s what my students would ask.” Right?
Eric Cross (35:02):
Well, I think it’s really effective to create empathy for the learner. Because I find myself in that position. I don’t know if some kind of memory displacement field happens to me when I sit in those workshops, but Hillary will ask a question that I know the answer to and I’m like, “I don’t want to answer the question. I don’t—I might be wrong.” And I teach the subject! And I embody what it’s like to be a student. And when I leave, I might have to go back and reference exactly what the lesson was, but I remember how I felt when I didn’t know. And very rarely as teachers do we get put in positions like that. And so it helps me be in the position of my students emotionally, of what it’s like. Even even the intentionality of how do you ask questions and not showing an affect on your face when somebody says the right answer or the wrong answer.
Desiré Whitmore (35:55):
Well, I’m still learning that. I’m not great at it. Julie is the mast.
Eric Cross (35:59):
Julie’s got it nailed.
Desiré Whitmore (36:00):
I’m still trying to learn from her. She’s amazing. And I really would like to get there one day. But I’m still not there. I’ll be like, “Oh! Oh! Well, that’s…”. I have a terrible poker face. So I’ll be like, “Oh yeah, but you think that? Maybe…”. That’s a piece of it that’s really important, right? It’s this not giving away the answer, even when you have the right answer. Allowing people to ask the questions and explore and become invested in the problem, before giving away the answer. That’s something that I learn here at the Exploratorium. And like I said, I learn every day. And it’s something that I think is so important for us as teachers to learn and try to implement. Because oftentimes you’ll come and you’ll have students who are like, “I’m too stupid. I don’t know the answer.” And then somebody else will say the answer, and then the student is like, “Yeah, I was right. I’m too stupid.’” But it’s like no! But if you have that student actually think about it, then the student—once they do hear the right answer—they might be like, “Oh yeah, that would make sense.” Instead of “I’m stupid.” It’s like, no, this is, “I explored this and I figured it out on my own.”
Eric Cross (37:08):
Things keep coming back to how this experience and the process of them learning science even outweighs the content of it. ‘Cause the content is almost easier to share, it’s easier to get, you can look it up really quickly. But in your story and in many other people’s stories, the exposure, the experience, how they’re going through that process—I know that’s something that I’ve learned a lot in just watching. Not teaching science, but actually the science of teaching. Sitting in the workshops and watching how we’re treated as students, how you interact with us, and then being able to take that back to the classroom. And just to add onto the value that it’s created, I think one thing that it’s also done is given us community. And in addition to being able to impact students, it’s also been able to build resilience in teachers. Because we as teachers can feel very isolated. And especially now when things are incredibly difficult, and every teacher’s experiencing Covid and shutdowns and low staffing across the country in different ways, when you don’t feel you have community or people that you can connect with, it just makes everything feel exponentially harder. And you’ve done a great job at being able to build community with us in our community of practice. The Exploratorium has been able to do that. And it’s something that I’m super-grateful for probably more than anything else is that through these last two years, being able to connect really made me feel like, “OK, we’re gonna be able to do this.” And it’s not just about Cross or my other teacher in eighth grade or my sixth grade teacher who’s doing this. That message, I think, is really, really important. I wanna ask this: Was there a teacher or an experience that impacted you or inspired you throughout your educational career? You know, kindergarten all the way to college? Was there a moment or a person or anything that that really stuck with you, that you felt maybe influenced who you became? Met you where you were at? I know you mentioned your chemistry teacher at that point, but is there anyone else, or was it that person that was really the person who sticks out for you?
Desiré Whitmore (39:21):
There actually have been a few. Of course, the first is my great-grandmother, Claudia Pairs. But I think in the fourth and fifth grade I had the same teacher. She stayed with us going from fourth to fifth grade. And fourth grade was a new school for me. New town. I was the only Black child in the school, me and my sister. And my teacher recognized that I had no real help at home, I guess? And she really kind of…she saw that I was really smart. She would give me extra assignments when she could tell I was bored. It meant that someone outside of my house cared about me in a way that I didn’t feel cared about at home. Her name is Ms. Comet. Mrs. Comet.
Eric Cross (40:11):
Like…comet?
Desiré Whitmore (40:13):
Yeah. Mrs. Fran Comet. And I’ve tried looking her up as an adult and I can’t find her. But I work with so many teachers, and I know how hard teaching is and how degrading it can be…or demoralizing, I guess, to not be appreciated. And so I know what it feels to me when a student has reached out and shown me like, “Hey, I’m now in dental school,” or “I’m now getting a PhD in science,” and I’m just like….
Eric Cross (40:40):
I got a message this morning on Instagram from a student. And none of my students use their real names in their Instagram handles. So I got a message from Moonshine. <Laugh> And I was a seventh grade teacher. And through deduction, deductive reasoning, I figured out who it was. This person’s now in college and they responded in that…you know, you get one of those every once in a while. And I feel it just fills your tank. It’s just so important that we—it’s funny because, kind of to your point, we don’t realize who or how we’re making impacts on people. And in what ways. We just know that we are. And I tell other teachers, I said, “You have one of the few professions where you fall asleep worrying about other people’s kids.” And it’s the words that we speak, the things that we do, people are always watching. I know, no pressure, right!? Hopefully, someone listening can find Ms. Comet.
Desiré Whitmore (41:37):
Ms. Comet. Teacher at Buena Vista Elementary School back in the ’80s. But your talk about this impact, it reminds me of the thing I wanted to say, but I didn’t. But I’m gonna tell you right now. I mentioned how science was not a priority when I went to school, in my hometown. That’s Lancaster, California. But recently I got a phone call from a family friend and she was so excited. And she called me to tell me that her daughter was super-excited when she picked her up from school. Because I was in her classroom. She said, “Auntie Desiré was in my class today! And she works on lasers! And she does spectroscopy! And I wanna learn about spectroscopy now. So can we call Auntie Desiré?” And I was like, “Wait, what?” My friend was kind of confused. She’s like, “Desiré didn’t tell me she was in town.” She had no idea why her daughter was saying I was in her classroom, ’cause I was not physically there. And then I had to put the pieces together and I was like, “Oh my God, your daughter’s in eighth grade already.” It made me feel really old, ’cause I know this girl from a little baby. But I was like, “Oh my God, that’s the eighth grade unit on light waves for Amplify that I wrote, and I’m featured as the scientist.” Because we have real scientists in the units. And they featured me in that one, in my laser lab. And so this little girl who knows me really well, who lives in my hometown, is seeing representation in science. She doesn’t necessarily know I’m a scientist. She knows that—I don’t know what she knows about me. She just knows I’m Auntie Desiré and, you know, I like gumbo at Christmas. That’s what she knows about me. <Laugh>. And so she comes back and she’s so excited ’cause now she knows so much more about me. And she knows that if I can do it and I came from where she’s at, she can do it too. And she was super-excited. And I was just…it brought me to tears. I was just crying in the car. I was driving <laugh> at the time and I was like, “This is amazing. Work that I did is teaching you and all of your friends in this tiny little town that you live in. And that to me is so important because now this little girl knows that, like, she knows me as just a normal human right. Who likes Star Trek and Star Wars and The Owl House. And now she’s over here like, “Oh my gosh, this normal human wrote the science curriculum that I’m learning from.” Which I think is just so fantastic. And it really brought home for me kind of the importance of my work and why I’m doing what I’m doing. And that’s pretty awesome. And I get messages from Instagram, you know, from teachers who are like, “Hey, did you work on this? ‘Cause you were featured in the video, but did you write this light waves unit?” And I’m like, “Yeah.” And they’ll tell me, “I have students, this is their favorite unit. I’ve gotten notes from students saying, ‘This was my favorite unit in all of middle school.’” And I’m like, “Ohhhhhh!”<Laugh>
Eric Cross (44:33):
That story just gives me chills. Because I just can imagine how surreal that must feel. And you’re directly making that impact on those kids. And I’m glad that you shared that story so that everyone can hear it, because it’s a powerful story and I lived—I feel I was living it through you, just now, as you were discussing it.
Desiré Whitmore (44:54):
Yeah.
Eric Cross (44:54):
And I feel that way in the classroom to a small degree, because I get to have—when my students create posters of scientists that we don’t typically see, I’ve got you on my list of scientists, and I’m they’re like…And I’m like, “I can call her!” Like, “Mr. Cross, you KNOW her?!” I’m like, “Yeah, she’s a friend of mine! I was talking to her the other day!” And they’re like, “Whoa. She works with lasers?!”
Desiré Whitmore (45:17):
<Whispers> I do.
Eric Cross (45:18):
Desiré. I’ve held you for so long and—
Desiré Whitmore (45:23):
Yes, I’m sorry! I told you, I talk so much! I’m a teacher!
Eric Cross (45:26):
No! No, no, no, no. It was great! I wanna honor your time. Can you tell everybody where they can find out more about you again?
Desiré Whitmore (45:33):
So first off, you can find me on Twitter at Darth Science, D A R T H S C I E N C E, and you can also find me at Instagram at Dr. Laser Chick: D R dot laser chick. Even though I don’t post on Instagram that much. I also have a website, which is laser chick dot net. I’m still working on it. It’s not the best website yet. But, you know, it’ll, it’ll be better in the future.
Eric Cross (46:02):
Would you be willing to come back later on in the year and do a part two?
Desiré Whitmore (46:07):
Oh, for sure. Yeah. So I can actually finish telling you the story of how I got into physics! ‘Cause I totally didn’t. ‘Cause I’m all over the place.
Eric Cross (46:15):
So, everybody, cliffhanger! Next time she comes back, she’ll continue to tell us the story. Desiré, thank you so much.
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Meet the guest
A Southern California native, Desiré earned an associate of science from Antelope Valley College, a bachelor of science in chemical engineering from UCLA, and a master of science and Ph.D. in chemical and material physics from UC Irvine. Her research focused on developing very fast laser and microscope systems that could capture molecules vibrating and rotating in real time. She was a postdoctoral fellow at UC Berkeley, where she designed and built attosecond lasers (the fastest laser pulses, which emit x-ray light, ever measured). At the Lawrence Hall of Science she wrote an all-digital K–8 science curriculum (Amplify Science), which aligned to the NGSS, with the Learning Design Group (LDG). Desiré left LDG to teach hands-on laser technology and physics courses at Irvine Valley College before joining the TI staff. She is the proud mom of Stella, a four-year-old boxer-pit mix. In her spare time, Desiré is restoring her 1967 VW bug.
About Science Connections
Welcome to Science Connections! Science is changing before our eyes, now more than ever. So…how do we help kids figure that out? We will bring on educators, scientists, and more to discuss the importance of high-quality science instruction. In this episode, hear from our host Eric Cross about his work engaging students as a K-8 science teacher. Listen here!
Steps for Interviewing
Amplify Professional Learning Specialist Applicants
Congratulations on being invited to interview for the Professional Learning Specialist role!
Please take these three steps in order to schedule and prepare for your interview.
Step 1: Review the PLS Flipbook
Step 2: Schedule your Interview
Step 3: Prepare for your Interview
Interviews for Cohort 2 will take place from April 27th – May 8th.
Step 1: Review the PLS Flipbook
Amplify Professional Learning Specialists (PLS) will be responsible for facilitating high-quality professional development (PD) to teachers and school leaders, ensuring educators feel confident taking steps to implement our programs and ultimately drive student success.
Please read the PLS flipbook to ensure you have a clear understanding of the role and ensure this is the right fit for you. These details are captured in pages 16 – 33 of the flipbook.
Several key PLS responsibilities are highlighted below:
- Delivering remote and onsite professional development for approximately 30-40 educators per session during the summer season (May – September 2026), possibly longer.
- Must be available to be scheduled during normal school hours (Monday–Friday) in all U.S. time zones.
- Must be available an average of three days per week on Monday through Friday from July 13–August 21. Three consecutive days is strongly recommended as it will potentially lead to more onsite delivery opportunities.
- PLSs who are current educators and returning to full-time roles at school/districts must have a return to work date after August 21st.
- Traveling via car, plane, and/or public transportation, sometimes with minimal advance notice and including overnight stay at hotels.
- Paying all travel-related expenses in advance, with reimbursements being processed 2-3 weeks following submission of the expense reimbursement requests.
Please reach out to pls_hiring@amplify.com if you have additional questions.
Step 2: Schedule Your Interview
Our second round of interviews will take place between April 27th – May 8th. We do not have any earlier interviews available, all available slots are shown on the calendars linked below.
Please schedule an interview for the specific role for which you have applied:
- Literacy or STEM Candidates: schedule a 30 minute interview by clicking here: “PLS Interviews: May 2026”
- Bilingual Candidates: schedule a 45 minute interview by clicking here: “Bilingual PLS Interviews: May 2026” only. You do not need to sign up for a separate 30 minute interview.
- Once you have scheduled your interview, you should receive a confirmation email from Calendly. If you do not receive this email, please reach out to PLS_hiring@amplify.com for support.
If you need to reschedule your interview, you may do so directly by clicking the reschedule link in the confirmation email from Calendly to select a new interview option during the current interview window. Once you have rescheduled, you will receive a new confirmation email and updated calendar invitation. Please do not sign up for more than one interview.
We ask that you only reschedule if absolutely necessary and request at least 24 hours notice prior to your interview day/time.
Step 3: Prepare for Interview
Prior to your scheduled interview, prepare your interview activity! Please view the video to the right for help preparing.
- Guidance for the task can be found here: PLS Performance Task Guidance Document
- You should come ready to share your screen via Google Meet and present the provided activity in under 5 minutes.
- Talking points are included for each screen to guide your presentation.
- During your interview we will be looking for proficiency with the following tech skills: independently sharing screen, speech matching animation, and moving from screen to screen with ease.
Offer, Onboarding, and Training
- Qualified candidates will receive an offer via email. The offer will include your product placement and regional assignment.
- If you accept the offer, our partner contracting agency will reach out to you to provide the necessary documentation to begin the onboarding process. This will include a background check. You will also need to provide college transcripts, please begin gathering these items.
- Once you have completed the onboarding process with our partner contracting agency, you will begin your official Amplify PLS onboarding process on May 11th for Cohort 1 or June 15th for Cohort 2. A majority of onboarding will be remote, with one in person training on June 6th – 7th for Cohort 1 and July 8th – 9th for Cohort 2. More details to come!
- Once you are certified, our PD Operations team will begin to schedule you for PD engagements within your region and across the country!
Info Session
Get more details from PD staff members about the PLS role, regional placement, the onboarding process, and ongoing support.
We will address the most common questions we receive:
- What is the role of a PLS?
- Where will I deliver sessions? What content will I deliver?
- How will onboarding work?
- How will I be supported?
The information session recording can be watched here.
Passcode: @N+4hmfi
Thank you for your interest!
Contact us with questions at pls_hiring@amplify.com
A closer look at grades 3–5
Amplify Science is based on the latest research on teaching and learning and helps teachers deliver age-appropriate, high-quality, literacy-rich instruction that enables students to take on the roles of scientists and engineers to solve real-world phenomena every day.
In the 3–5 classroom, this looks like students:
- Collecting evidence from a variety of sources.
- Making sense of evidence in a variety of ways.
- Formulating convincing scientific arguments.
Program structure
Our cyclical lesson design ensures students receive multiple exposures to concepts through a variety of modalities. As they progress through the lessons within a unit, students build and deepen their understanding, increasing their ability to develop and refine complex explanations of the unit’s phenomenon.
It’s this proven program structure and lesson design that enables Amplify Science California to teach less, but achieve more. Rather than asking teachers to wade through unnecessary content, we designed our 3–5 program to address 100% of the California NGSS in just 88 days.
Scope and sequence
Every year of our grades 3–5 sequence consists of 4 units and 88 lessons. Said another way, each unit contains 20 lessons plus two dedicated assessment days (a Pre-Unit Assessment and End-of-Unit Assessment).
Lessons for grades 3–5 are written to last a minimum of 60 minutes, though teachers can expand or contract the timing to meet their needs.
Unit types
Each unit delivers three-dimensional learning experiences and engages students in gathering evidence from a rich collection of sources, while also emphasizing a particular science and engineering practice.
In grades 3–5:
- One unit emphasizes the practice of investigation.
- One unit emphasizes the practice of modeling.
- One unit emphasizes the practice of engineering design.
- One unit emphasizes the practice of argumentation.
Investigation Units
Investigation units focus on the process of strategically developing investigations and gathering data to answer questions. Students are first asked to consider questions about what happens in the natural world and why, and are then involved in designing and conducting investigations that produce data to help answer those questions.
Modeling Units
Modeling units provide extra support to students engaging in the practice of modeling. Students use physical models, investigate with computer models, and create their own diagrams to help them visualize what might be happening on the nanoscale.
Engineering Design Units
Engineering design units provide opportunities for students to solve complex problems by applying science principles to the design of functional solutions, and iteratively testing those solutions to determine how well they meet preset criteria.
Argumentation units
Argumentation units provide students with regular opportunities to explore and discuss available evidence, time and support to consider how evidence may be leveraged in support of claims, and independence that increases as they mount written arguments in support of their claims.
Units at a glance
Balancing Forces
Domain: Physical Science
Unit type: Modeling
Student role: Engineers
Phenomenon: The town of Faraday is getting a new train that floats above its tracks.
Inheritance and Traits
Domain: Life Science
Unit type: Investigation
Student role: Wildlife biologists
Phenomenon: An adopted wolf in Graystone National Park (“Wolf 44”) has some traits that appear similar to one wolf pack in the park and other traits that appear to be similar to a different wolf pack.
Environments and Survival
Domains: Life Science, Engineering Design
Unit type: Engineering design
Student role: Biomimicry engineers
Phenomenon: Over the last 10 years, a population of grove snails has changed: The number of grove snails with yellow shells has decreased, while the number of snails with banded shells has increased.
Weather and Climate
Domains: Earth and Space Science, Engineering Design
Unit type: Argumentation
Student role: Meteorologists
Phenomenon: Three different islands, each a contender for becoming an Orangutan reserve, experience different weather patterns.
Energy Conversions
Domains: Physical Science, Earth and Space Science, Engineering Design
Unit type: Engineering design
Student role: System engineers
Phenomenon: The fictional town of Ergstown experiences frequent blackouts.
Vision and Light
Domain: Physical Science, Life Science, Engineering Design
Unit type: Investigation
Student role: Conservation biologists
Phenomenon: The population of Tokay geckos in a rain forest in the Philippines has decreased since the installation of new highway lights.
Earth’s Features
Domain: Earth and Space Science
Unit type: Argumentation
Student role: Geologists
Phenomenon: A mysterious fossil is discovered in a canyon within the fictional Desert Rocks National Park.
Waves, Energy, and Information
Domains: Physical Science, Life Science, Earth and Space Science, Engineering Design
Unit type: Modeling
Student role: Marine scientists
Phenomenon: Mother dolphins in the fictional Blue Bay National Park seem to be communicating with their calves when they are separated at a distance underwater.
Patterns of Earth and Sky
Domains: Physical Science, Earth and Space Science
Unit type: Investigation
Student role: Astronomers
Phenomenon: An ancient artifact depicts what we see in the sky at different times — the sun during the daytime and different stars during the nighttime — but it is missing a piece.
Modeling Matter
Domain: Physical Science
Unit type: Modeling
Student role: Food scientists
Phenomenon: Chromatography is a process for separating mixtures. Some solids dissolve in a salad dressing while others do not. Oil and vinegar appear to separate when mixed in a salad dressing.
The Earth System
Domains: Earth and Space Science, Physical Science, Engineering Design
Unit type: Engineering Design
Student role: Water resource engineers
Phenomenon: East Ferris, a city on one side of the fictional Ferris Island, is experiencing a water shortage, while West Ferris is not.
Ecosystem Restoration
Domains:Physical Science, Life Science, Earth and Space Science, Engineering Design
Unit type: Argumentation
Student role: Ecologists
Phenomenon: The jaguars, sloths, and cecropia trees in a reforested section of a Costa Rican rain forest are not growing and thriving.
Resources
What instructional coherence really looks like
What instructional coherence really looks like
Welcome, Program 3 reviewers!
We’re honored to introduce you to Amplify California Language Arts. We’re confident you’ll find this comprehensive program to be a powerful tool for bringing the vision of the California ELA/ELD Framework to life in classrooms across the state.
Please start with the video on the right to learn how to navigate the program and access key features referenced within our submission. Below you’ll find additional resources to support your review.
Your review samples
We’re excited for you to begin your review of Amplify California Language Arts, a comprehensive biliteracy program for kindergarten through grade 6.
Reviewer Binders (K–6)
Your physical samples should have arrived in grade-specific boxes with three Reviewer Binders.
- The first binder will contain logistical program review information and the printed Evaluation Criteria Map.
- The second binder will contain the printed Standards Maps for grades K–2.
- The third binder will contain the printed Standards Maps for grades 3–6.
Physical samples (trade books)
Your review of the program will be entirely digital with the exception of the trade books that you will be receiving as physical samples. You can expect to receive 13 boxes of physical materials for your review. Twelve boxes of trade books, one for each grade K–5, in English and Spanish, and one box containing your Reviewer Binders.
As you begin the process of organizing your materials, please refer to the inventory checklist found inside each box as well as within your Reviewer Binder.
Digital review materials
In order to access your digital review materials, you’ll need to log in to our platform using your unique login credentials found on a Digital Review Credential flyer inside of your Reviewer Binder. Once you have located the flyer:
- Click the orange button below to access the platform.
- Click “Log in with Amplify.”
- Enter the username and password provided on your Digital Review Credential flyer.
Navigation tips
Before you get started, please review these important functionality notes:
Criteria Map and Standards Maps must be opened on Microsoft Word on your desktop to function as intended. If you open the documents without Microsoft Word on your desktop, citations will be cut off at the bottom of most tables within the document.
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[Reviewer program navigation video] Grades K–5
[Reviewer program navigation video] Grade 6
Click here for additional information on navigating the program for grade 6.
Category 1: English Language Arts (ELA) and English Language Development (ELD) content/alignment to standards
Evaluation Criteria Map
Linked below is the Evaluation Criteria Map. Please note that you will need to be logged into the digital platform to access the links in the Evaluation Criteria Map.
ELA Standards Maps
The links below provide the Standards Maps for Amplify California Language Arts for each grade level.
ELD Standards Maps
Category 2: Program organization
Amplify California Language Arts’ biliteracy program is a comprehensive curriculum provides a full year of evidence-based instruction for each grade level, with both integrated and designated English Language Development instruction designed to give multilingual/English learners the tools to thrive. Amplify’s biliteracy program for grades K–6 includes:
- Core English language arts instruction: Amplify Core Knowledge Language Arts (CKLA) California (grades K–5) and Amplify ELA California (grade 6) covering knowledge building and foundational skills.
- Provides upper grade foundational skills instruction for grades 3–6.
- Core Spanish language arts instruction: Amplify Caminos California, a fully parallel SLA program that works in tandem with English core instruction across all grades.
- Provides upper grade foundational skills instruction for grades 3–6.
- Designated English Language Development: Language Studio California is the designated English Language Development companion that directly aligns with and supports core English instruction.
- Newcomer Support: Amplify California Language Arts Newcomer Support to facilitate instruction for students who are new to both English and the United States.
Program structure
Amplify’s California Language Arts programs are built on what the research shows: Strong readers need both word recognition and language comprehension. Our comprehensive curriculum suite follows the Simple View of Reading bringing together foundational skills and knowledge building to deliver instruction grounded in the Science of Reading.
This model is integral to the structure of the Amplify biliteracy program, which directly aligns with the CA CCSS ELA and ELD standards by combining rigorous decoding and skills instruction with research-based knowledge and language development instruction. In its early grades, the Amplify biliteracy program uses a two-strand structure—Skills/Lectoescritura and Knowledge/Conocimiento—to effectively address this learning challenge while meeting standards expectations for both language development and academic content mastery.
[Reviewer highlight video] Program organization for Category 2
[Reviewer highlight video] Program structure for grades K–2
[Reviewer highlight video] Program structure for grades 3–5
[Reviewer highlight video] Program structure for grade 6
Amplify Caminos California lessons are designed to allow all students time to work toward learning objectives, including peer collaboration and discussion. Since each lesson activity is aligned to subsequent activities, students’ understanding and analysis develops progressively throughout the lesson.
Each lesson follows a predictable structure with clearly marked components, beginning with warm-up routines, progressing through explicit instruction with guided practice, and concluding with independent application activities. The program provides detailed teacher language, including question stems and discussion prompts, ensuring clear and consistent delivery of instruction.
Amplify CKLA California and Amplify Caminos California empower teachers to deliver effective instruction and keep students engaged with the following resources:
- Teacher Guides
- Assessment Guides
- Authentic texts and trade books
- Knowledge Image Cards
- Knowledge Flip Books
- Remediation and intervention resources
- Decodable readers
- Student Readers and novels
- Student Activity Books
- Dedicated ELD support with Language Studio California
- Poet’s Journals
- eReaders
- Sound Library featuring articulation videos and songs
- Instructional routine modeling videos
- Assignable Practice Games
- On-demand professional development
Amplify ELA California students stay engaged with the following resources:
- Teacher Guides that include:
- Detailed lesson plans
- Standards alignment and exit tickets
- Real-time differentiation strategies
- Robust reporting
- Student Editions that include:
- High-quality narrative and informational texts
- Videos, audio supports, and digital experiences that capture their attention
- Personal Writing Journal to keep all student writing in one place
- Dedicated ELD support with Language Studio California
- Trade books
Core literacy philosophy
Support every learner. Meet all learning needs with a Multi-Tiered System of Supports (MTSS) that brings together universal screening, scaffolded core instruction, support for multilingual/English learners, and data-driven intervention to ensure every student gets what they need to succeed.
Deliver consistent foundational skills instruction. Daily explicit, systematic skills instruction in grades K–2, with targeted yet flexible support for students still building decoding confidence in grades 3–6, ensures mastery of essential reading foundations.
Build lasting knowledge across all grades. Through coherently sequenced, content-rich instruction that revisits key vocabulary and concepts with increasing complexity, students build meaningful connections that deepen their vocabulary and reading comprehension.
Strengthen reading through writing at every level. Regular writing instruction grounded in the Science of Writing supports reading comprehension, improves sentence-level writing, and provides the foundation for high-quality composition. As students progress through the upper grades, they engage in increasingly complex analytical tasks—synthesizing ideas, drawing generalizations, and interpreting multiple textual layers through both focused quick-writes and comprehensive essays.
Foster oral language development. Structured opportunities for academic conversation and evidence-based dialogue build students’ ability to express complex ideas with precision and allow them to participate confidently in classroom discussions.
Measure growth with comprehensive assessments. Assessments range from in-the-moment checks for understanding to summative assessments that measure progress toward skills mastery and standards proficiency, providing the data needed to drive targeted instruction.
Scope and sequence
Below you can view the scope and sequence documents for each grade level.
- Kindergarten
- Grade 1
- Grade 2
- Grade 3
- Grade 4
- Grade 5
- Grade 6
- Newcomer Support Grades K–6
Routines
Amplify CKLA California, Amplify Caminos California, and Amplify ELA California include several structured instructional routines that provide predictable patterns for both teachers and students:
Discussion and collaboration routines:
- Turn and Talk: Partners discuss text-specific content using sentence starters and frames
- Think-Pair-Share: Students engage in individual thinking, partner discussion, and whole-class sharing
- Partner reading: Students sit shoulder-to-shoulder, taking turns reading and listening
Foundational Skills routines:
- Sound-spelling review: Warm-up activities that reinforce phonics patterns
- Oral blending warm-ups: Teacher-guided practice progressing to independent application
- Finger-tapping: Techniques for blending sounds
- Chaining activities: Students manipulate letters to transform one word into another
- Word Work: Daily short activities focused on domain-specific and academic vocabulary
Knowledge-building routines:
- Teacher modeling: Demonstration of proper intonation, expression, and pacing
- Choral reading: Whole-class reading practice
- Partner reading: Paired fluency practice
Close reading routines
The program includes carefully structured close reading activities that guide students through multiple encounters with complex texts. These routines help students develop deeper comprehension through systematic analysis and discussion.
Each routine includes comprehensive instructional guides with clear-cut directions for implementation, straightforward explanations of concepts, and suggestions for discussion.
Cross-Linguistic Transfer routines
The Cross-Linguistic Transfer (CLT) routines are easy-to-implement, 10–15 minute mini-lessons designed to help bridge English and Spanish literacy and language development. These structured routines are organized by grade bands for K–2, grades 3–5 and grade 6, covering five skill areas:
- Oral language
- Reading
- Vocabulary
- Language
- Writing
[Reviewer highlight video] Amplify’s program alignment to Cross-Linguistic Transfer criteria
Designated English Language Development materials
Language Studio California is a K–8 content-based companion for English language learners. Built on Amplify CKLA California and Amplify ELA California’s carefully sequenced Knowledge Domains, it combines engaging content knowledge with targeted supports and research-based strategies to help students move swiftly toward language proficiency. This program includes:
- Real-world content to provide authentic opportunities to practice reading, writing, speaking, and listening.
- Scaffolding strategies and differentiated instruction to offer targeted support along five English proficiency levels.
- Progress monitoring tools to help teachers provide consistent and effective support.
- Teacher Guides that:
- Provide impactful progress monitoring tools including formative and summative assessments, and Language Proficiency Assessment rubrics.
- Offer varied differentiation strategies including Support, Challenge, and Access supports in each lesson segment.
- Are organized into thoughtful lesson segments—Talk Time, Building Background, On Stage and more—that make learning objectives concrete.
- Activities that:
- Expand on domain knowledge from core content and read-alouds and prompt collaborative conversation to practice oral fluency.
- Support hands-on language activities to promote authentic interaction in the classroom.
- Help students bridge experiences and knowledge with images, vocabulary activities, graphic organizers, anticipation guides, writing space, and more.
Category 3: Assessments
Systematic MTSS alignment
In alignment with the additional 2025 Guidance 3.1.a, the assessment systems align with MTSS tiers, including universal screening, diagnostic assessments for students demonstrating a need for additional support, and progress monitoring tools that complement California’s required reading difficulties screening schedule per SB 114.
| Tier 1: Universal/ differentiated support | Tier 2: Supplemental/ targeted support | Tier 3: Intensified/ intensive support | |
| Core instruction assessments Frequency of administration | Amplify CKLA California, Amplify Caminos California, Amplify ELA California assessments Daily, Weekly, Monthly | Amplify CKLA California, Amplify Caminos California, Amplify ELA California assessments Daily, Weekly, Monthly | Amplify CKLA California, Amplify Caminos California, Amplify ELA California assessments Daily, Weekly, Monthly |
| Universal screening assessments Frequency of administration | mCLASS DIBELS and Lectura 3 times per year – BOY, MOY, EOY | mCLASS DIBELS and Lectura 3 times per year – BOY, MOY, EOY | mCLASS DIBELS and Lectura 3 times per year – BOY, MOY, EOY |
| Formal progress monitoring assessments Frequency of administration | mCLASS DIBELS and Lectura 3 times per year – BOY, MOY, EOY | mCLASS DIBELS and Lectura Monthly | mCLASS DIBELS and Lectura Bi-weekly |
| Informal progress monitoring assessments Frequency of administration | Amplify CKLA California, Amplify Caminos California, Amplify ELA California core assessments Daily | Intervention Toolkit progress monitoring assessments When linked to a lesson in the toolkit | Intervention Toolkit progress monitoring assessments When linked to a lesson in the toolkit |
| Diagnostic assessment Frequency of administration | Amplify skill diagnostic assessment Amplify Spanish skill diagnostic assessment Optional after universal screening assessment is administered | Amplify skill diagnostic assessment Amplify Spanish skill diagnostic assessment After universal screening assessment is administered |
Universal assessment system
Amplify’s mCLASS® DIBELS® 8th Edition (K–8) and mCLASS Lectura (K–6) are universal and dyslexia screening assessments that should be administered three times per year (BOY, MOY, and EOY) to all students. The assessments evaluate student literacy risk, determine progress toward grade-level goals, and indicate the level of instructional support a student may need. Beginning-of-year screenings require adequate instructional time before administration, particularly in grades K–1, while mid-year and end-of-year assessments evaluate instructional effectiveness and guide tier placement adjustments. These screenings also identify students at risk for dyslexia. Universal screening provides essential data for targeting instruction and measuring instructional system effectiveness.
Core instruction assessments
Amplify CKLA California, Amplify Caminos California, and Amplify ELA California provide a comprehensive suite of assessments for grades K–6 that range from low-stakes, informal formative assessments to more formal summative assessments. These assessments incorporate a variety of methods and question types, including multiple-choice questions, open-ended questions, and oral and written responses.
Formative assessments:
- Checks for Understanding: Incorporated into each lesson segment throughout daily instruction. Quick pulse-checks that provide immediate feedback during lesson delivery (grades K–5).
- Daily formative assessments: Highlighted moments within each lesson for teachers to plan to track mastery of Primary Focus objectives and standards of each lesson to get a clear snapshot of individual and whole-class progress (grades K–5).
- Activity pages: Completed as part of lessons and can be used to assess lesson content understanding through various formats (grades K–5).
- Exit Tickets: Located at the end of lessons, these provide a quick gauge of students’ ability to meet the lesson’s focus standards (grade 6).
- Writing Prompts: Prompts integrated throughout lessons during writing activities that provide skill snapshots within lessons and tracks patterns of skill development over time (grade 6).
- Independent reading activities (Solos): At the end of every lesson, students complete an independent reading activity (“Solo”) with reading questions that are scored to measure comprehension (grade 6).
Summative assessments:
- Skills end-of-unit assessments (grades K–2)
- Knowledge end-of-domain assessments (grades K–2)
- End-of-unit assessments (grades 3–5)
- Unit essays: A culminating end-of-unit set of lessons that guide students through crafting an essay with a rubric to score mastery of writing skills (grade 6)
- Unit reading assessments: Auto-scored responses and two constructed response items evaluate comprehension, content understanding, and reading skills using the passages students read during the unit (grade 6)
Performance assessments
Student Performance Assessments are multi-day assessments administered in Grades K–5 at the beginning, middle, and end of year to help teachers gauge student mastery of grade-level Core content. These assessments provide critical data to help teachers set targeted instructional goals and monitor individual and class-wide progress towards core objectives.
Progress monitoring
Amplify’s mCLASS® DIBELS® 8th Edition and mCLASS Lectura provide formal progress monitoring in the discrete skills that are indicative of reading growth and predictive of overall success to provide the most instructionally meaningful information to teachers.
Informal progress monitoring tools can be found within the Intervention Toolkit, including materials for teachers to record, track, and evaluate student progress.
Diagnostic assessment
Interventions within Amplify’s literacy programs are informed by a skill diagnostic assessment that provides detailed data on foundational literacy skill deficits. The Amplify Skill Diagnostic Assessment and Amplify Spanish Skill Diagnostic assessment serve as critical tools in this process, administered specifically to students identified as at risk for reading difficulty through universal screening assessments—particularly those demonstrating mCLASS DIBELS 8th Edition or mCLASS Lectura composite scores in the Well Below or Below Benchmark ranges. These diagnostic assessments provide teachers with the precise skills to begin intervention and remediation.
Category 4: Universal Access
Amplify CKLA California, Amplify Caminos California, and Amplify ELA California are developed using the Universal Design for Learning framework to proactively ensure that all learners can access and participate in meaningful, challenging learning opportunities.
Universal Design for Learning
Amplify CKLA California, Amplify Caminos California, and Amplify ELA California incorporate opportunities for engagement, representation, action, and expression based on the guidelines of Universal Design for Learning.
- Multiple Means of Engagement: The programs incorporate interesting and motivating ways for students to interact with information and content. The Universal Access section in the introduction of each lesson provides specific lesson-level options based on the needs of individual classrooms and students. Scaffolding for students with various levels of need is incorporated into the design of each lesson.
- Multiple Means of Representation: The programs provide multiple means of presenting content to maximize student understanding. This includes digital component files that allow for a range of presentations of images and text to support learning. Amplify provides access to universal supports such as point-of-use audio for all core texts, embedded definitions for critical vocabulary, and glossaries in multiple languages. The programs include clarification on language found throughout the program, with sidebars that include support on transition words and syntax, and illustrations to help students understand the concepts they are learning.
- Multiple Means of Action and Expression: The programs include a range of methods for all students, including Multilingual/English Learners, to navigate and demonstrate learning. This includes physical actions, a range of methods for response, appropriate tools for composition, and varied scaffolding. Lessons provide multiple ways for students to interact with text, allowing their brains to process the language through distinct pathways. Activities harness multiple learning modes, using media tools, digital apps, and a variety of visual and physical experiences to strategically support and enhance student learning.
- Accessibility: Universal access features include visual aids, enlarged materials, physical objects, and multiple learning modalities through activities like Push & Say and Wiggle Cards. The Universal Access section in the introduction of each lesson provides specific lesson-level options based on the needs of individual classrooms and students.
Embedded differentiation
Amplify CKLA California, Amplify Caminos California, and Amplify ELA California provide built-in differentiation strategies in every lesson for all students.
- Pre-teaching supports include mini-lessons on:
- Core vocabulary building
- Core connections
- Essential background information building
- What Have We Already Learned?/What Do We Already Know?
- Differentiated Support for Core Instruction tables, located in the overview of each K–2 Skills Teacher Guide, provide a list of specific opportunities for reteaching and additional support in each lesson based on skill.
- Support and Challenge Sidebars in lesson margins offer educators immediate guidance in implementing point-of-use differentiation techniques.
- Flexible Grouping within lessons provides opportunities for teachers to facilitate small groups, partners, or individualized support based on students’ needs. In the Skills Strand, teachers receive specific guidance for differentiated small group instruction, with targeted support and activities outlined for both Group 1 (students needing additional support) and Group 2 (on-level students) based on data.
- Amplify ELA California and Amplify Caminos California provide point-of-use supports embedded within key core lesson activities with six levels of differentiation. The goal of these supports is to fully enable access to grade-level content for all students, including students with disabilities, English learners, and students ready for an additional level of challenge.
- The Universal Access section of Advance Preparation in each lesson includes varied strategies to ensure all students can access and engage in each lesson.
- Frequent use of graphic organizers and visual supports in lessons provide opportunities for differentiation based on need. The program also includes a variety of technological supports, such as eReaders with audio.
- Extension opportunities are suggested throughout lessons, often embedded in writing tasks, which include prompts to use more complex and descriptive vocabulary, figurative language, multi-clause and complex sentences, and informational text characteristics.
Assessment-driven MTSS resources
- The K–6 Intervention Toolkit is available online and provides easy-to-use resources that assist teachers in filling gaps in students’ reading skills, with activities to support print concepts, phonological awareness, phonics, fluency, and other key skills.
- Fluency packets (Grades 2–6)
- Foundational Skills Intervention Program for Grades 3–6 support students who would benefit from direct and explicit intervention instruction in the full continuum of foundational skills in the upper grades
- Flexible Instructional Time including:
- Pausing Points built into the curriculum that provide teachers with dedicated time to address specific student needs through targeted reteaching, remediation, practice, and extension activities
- Pausing Point activities designed to support multilingual/English learners’ competence and confidence through differentiated whole-group, small-group, or individual instruction
- Boost Reading and Boost Lectura are student-led digital intervention programs that follow the scope and sequences of Amplify CKLA California and Amplify Caminos California respectively, to reinforce the same foundational skills taught in core instruction. It integrates easily into daily routines, while the robust data provided by mCLASS® DIBELS® 8th Edition offers a detailed view of how students progress across all instructional tiers.
Category 5: Instructional Planning and Teacher Support
Amplify CKLA California, Amplify Caminos California, and Amplify ELA California teachers are empowered to deliver effective instruction with various print and digital resources. The program provides comprehensive planning and support materials designed to help teachers prepare for and execute lessons effectively and fulfill the requirements of Category 5.
Implementation supports across K–6
Planning and preparation resources
- Unit Overviews that provide important background and context for the texts students will read, including highlighted elements within the text and guidance for how students will work with those elements
- Sub-unit Overviews (Grade 6) that provide an overview of Lesson Objectives and reading and writing assignments, as well as a list of any projections, multimedia, or digital apps that can be projected from the teacher’s included digital license
- Lesson-by-lesson preparation checklists (Grade 6) accompanying each Sub-unit Overview
- Lesson Briefs for each individual lesson providing important background and context
- Content knowledge materials regarding topics that students will examine
Point-of-use instructional guidance
- Teacher Editions that feature insets of the same text and activity instructions as the corresponding Student Edition, wrapping teacher instruction around these materials
- Activity guidance at point of use
- Lesson standards clearly called out
- Discussion suggestions embedded in lessons
- Differentiation tips at point of use
- Detailed Instructional Guides in each activity that include sequencing and grouping suggestions, tips for facilitating discussion, possible student responses and exemplars
- On-the-Fly supports (Grade 6)—quick call-outs to the identifying features of “on track” and “needs support” students accompanied by short models of student guidance to foster strong performance
Multimedia and digital support
- Teacher tip videos provide modeling and guidance for implementing key foundational skills routines within the program
- Digital platform access where teachers can access printable PDFs of differentiated support materials for multilingual/English learners and students struggling to read, including translated Unit Background and Context documents and Text Previews
- Teacher Dashboard and reporting tools provide real-time visibility into student progress and work for immediate instructional response
Caregiver supports
Communication and overview resources
- Caregiver Hub available in English and Spanish that provides an overview of the curriculum
- Caregiver Letters for each K–2 Knowledge Domain and unit in Grades 3–5 that provide an overview of the content, the skills students learn, as well as practical methods that continue the learning and knowledge building at home
- Unit-specific Caregiver Letters (Grade 6) that provide detailed information regarding what students will read and learn in each unit, including conversation starters that allow caregivers to ask questions and discuss specific aspects of a unit with their student
- Welcome letters that explain the assessment and placement process while inviting parent involvement and offering support
- Editable Home-School Communication letters available in English and Spanish
- Editable Progress Reports for teachers to update parents and guardians on what their child is learning
Content and learning support materials
- Unit Background and Context documents that provide an introduction and overview to the unit’s topic and themes, available in English and Spanish
- Text Previews that provide a brief introduction to formative, independent reading assignments (called Solos in Grade 6), available in English and Spanish
- Unit Overview and Support documents (Grade 6) designed for caregivers that provide information about important questions, assignments, and key aspects of the unit texts, available in English and Spanish
- Conversation starters included in Knowledge Strand Caregiver Letters to discuss domain topics at home
Home practice and extension activities
- Take-Home pages in the Skills Strand that include copies of decodable passages, enabling students to share their reading progress with families and continue practicing their skills outside of school
- Take-Home Letters in the Skills Strand that provide specific guidance for parents to support skills practice at home, such as sound-sorting activities, with detailed instructions and materials for home practice activities
- Take-Home pages in the Knowledge Strand that provide suggested activities families can do together to reinforce and extend learning beyond the classroom
- Games and activities on Take-Home Pages that extend classroom instruction, including all the materials and instruction necessary to help families assist students in a fun and engaging way
- Digital access to decodable texts through the Amplify Caregiver Hub, allowing students to practice their reading skills both in class and at home
- Weekly spelling lists and directions to decoding activities that can be practiced at home
Welcome, K–8 Program 2 reviewers!
We’re honored to introduce you to Amplify California Language Arts. We’re confident you’ll find this comprehensive program to be a powerful tool for bringing the vision of the California ELA/ELD Framework to life in classrooms across the state.
Please start with the video on the right to learn how to navigate the program and access key features referenced within our submission. Below you’ll find additional resources to support your review.
Your review samples
We’re excited for you to begin your review of Amplify Core Knowledge Language Arts (CKLA) California and Amplify ELA California, Language Studio California for grades K–8. Physical and digital review materials will vary by grade level.
Reviewer Binders (K–8)
Your physical samples should have arrived in grade-specific boxes with three Reviewer Binders.
- The first binder will contain logistical program review information and the printed Evaluation Criteria Map.
- The second binder will contain the printed Standards Maps for grades K–4.
- The third binder will contain the printed Standards Maps for grades 5–8.
Physical samples (K–5)
You can expect to receive 15 boxes of physical materials for your review. As you begin the process of organizing your materials, please refer to the inventory checklist found inside each box as well as within your Reviewer Binder. Please note you will not receive any physical samples for grades 6–8 ELA or Language Studio for grades K-8. Your review of the program for grades 6–8 ELA and Language Studio for grades K-8 will be entirely digital.
Digital samples
In order to access your digital samples, you’ll need to log in to our platform using your unique login credentials found on a Digital Review Credential flyer inside of your Reviewer Binder. Once you have located the flyer:
- Click the orange button below to access the platform.
- Click “Log in with Amplify.”
- Enter the username and password provided on your Digital Review Credential flyer.
Navigation tips
Before you get started, please review these important functionality notes:
Criteria Map and Standards Maps must be opened on Microsoft Word on your desktop to function as intended. If you open the documents without Microsoft Word on your desktop, citations will be cut off at the bottom of most tables within the document.
Many of our citations are deep-links to PDFs, meaning they will take you to the right page or the first page in the sequence for the citation in question. To ensure this functionality works, please disable any PDF-viewing extensions or plug-ins such as Adobe Acrobat Pro Browser Extension.
[Reviewer program navigation video] Grades K–5
[Reviewer program navigation video] Grades 6–8
Click here for additional information on navigating the digital materials for grades 6–8.
Category 1: English Language Arts (ELA) and English Language Development (ELD) Content/Alignment to Standards
Evaluation Criteria Map
Linked below is the Evaluation Criteria Map for grades K–8. Please note that you will need to be logged into the digital platform to access the links in the Evaluation Criteria Map.
ELA Standards Maps
The links below provide the Standards Maps for Amplify California Language Arts for each grade level. Please note that you will need to be logged into the digital platform to access the links in the Standards Maps.
ELD Standards Maps
The links below provide the ELD Standards Maps for Amplify California Core Language Arts for each grade level.
Category 2: Program Organization
The Amplify California Language Arts Program 2 submission includes Amplify CKLA California for Grades K–5, Amplify ELA California for Grades 6–8, and Amplify Language Studio California for Grades K–8. This comprehensive curriculum provides a full year of evidence-based instruction for each grade level, with both integrated and designated English Language Development instruction designed to give English learners the tools to thrive.
Program structure
Amplify’s California Language Arts programs are built on what the research shows: Strong readers need both word recognition and language comprehension. Our comprehensive curriculum suite follows the Simple View of Reading and The Reading Rope–bringing together foundational skills and knowledge building to deliver instruction grounded in the Science of Reading.
Each lesson follows a predictable structure with clearly marked components, beginning with warm-up routines, progressing through explicit instruction with guided practice, and concluding with independent application activities. The program provides detailed teacher language, including question stems and discussion prompts, ensuring clear and consistent delivery of instruction.
[Reviewer highlight video] Program organization for Category 2
[Reviewer highlight video] Program structure for grades K–2
[Reviewer highlight video] Program structure for grades 3–5
[Reviewer highlight video] Program structure for grades 6–8
Amplify CKLA California empowers teachers to deliver effective instruction and keeps students engaged with with the following resources:
- Teacher Guides
- Assessment Guides
- Authentic texts and trade books
- Knowledge Image Cards
- Knowledge Flip Books
- Remediation and intervention resources
- Decodable readers
- Student Readers and novels
- Student Activity Books
- Dedicated ELD support with Language Studio California
- Poet’s Journals
- eReaders
- Sound Library featuring articulation videos and songs
- Instructional routine modeling videos
- Assignable Practice Games
- On-demand professional development
Amplify ELA California students stay engaged with the following resources:
- Teacher Guides that include:
- Detailed lesson plans
- Standards alignment and exit tickets
- Real-time differentiation strategies
- Robust reporting
- Student Editions that include:
- High-quality narrative and informational texts
- Videos, audio supports, and digital experiences that capture their attention
- Personal Writing Journal to keep all student writing in one place
- Dedicated ELD support with Language Studio California
- Trade Books
Core literacy philosophy
Support every learner. Meet all learning needs with a Multi-Tiered System of Supports (MTSS) that brings together universal screening, scaffolded core instruction, support for English learners, and data-driven intervention to ensure every student gets what they need to succeed.
Provide intentional ELD support. Honor students’ linguistic assets while building academic English through both integrated and designated instruction.
Deliver consistent foundational skills instruction. Daily explicit, systematic skills instruction in grades K–2, with targeted yet flexible support for students still building decoding confidence in grades 3–8, ensures mastery of essential reading foundations.
Build lasting knowledge across all grades. Through coherently sequenced, content-rich instruction that revisits key vocabulary and concepts with increasing complexity, students build meaningful connections that deepen their vocabulary and reading comprehension.
Strengthen reading through writing at every level. Regular writing instruction grounded in the Science of Writing supports reading comprehension, improves sentence-level writing, and provides the foundation for high-quality composition. As students progress through the upper grades, they engage in increasingly complex analytical tasks—synthesizing ideas, drawing generalizations, and interpreting multiple textual layers through both focused quick-writes and comprehensive essays.
Foster oral language development. Structured opportunities for academic conversation and evidence-based dialogue build students’ ability to express complex ideas with precision and allow them to participate confidently in classroom discussions.
Measure growth with comprehensive assessments. Assessments range from in-the-moment checks for understanding to summative assessments that measure progress toward skills mastery and standards proficiency, providing the data needed to drive targeted instruction.
Scope and sequence
Below you can view the scope and sequence for each grade level.
- Kindergarten
- Grade 1
- Grade 2
- Grade 3
- Grade 4
- Grade 5
- Grade 6
- Grade 7
- Grade 8
- Newcomer Support Grades K–8
Routines
Amplify CKLA California and Amplify ELA California include several structured instructional routines that provide predictable patterns for both teachers and students:
Discussion and collaboration routines:
- Turn and Talk: Partners discuss text-specific content using sentence starters and frames
- Think-Pair-Share: Students engage in individual thinking, partner discussion, and whole-class sharing
- Partner reading: Students sit shoulder-to-shoulder, taking turns reading and listening
Foundational Skills routines:
- Sound-spelling review: Warm-up activities that reinforce phonics patterns
- Oral blending warm-ups: Teacher-guided practice progressing to independent application
- Finger-tapping: Techniques for blending sounds
- Chaining activities: Students manipulate letters to transform one word into another
- Word Work: Daily short activities focused on domain-specific and academic vocabulary
Knowledge-Building Routines:
- Teacher modeling: Demonstration of proper intonation, expression, and pacing
- Choral reading: Whole-class reading practice
- Partner reading: Paired fluency practice
Close reading routines
The program includes carefully structured close reading activities that guide students through multiple encounters with complex texts. These routines help students develop deeper comprehension through systematic analysis and discussion.
Each routine includes comprehensive instructional guides with clear-cut directions for implementation, straightforward explanations of concepts, and suggestions for discussion.
Designated English Language Development materials
Language Studio California is a K–8 content-based companion for English language learners. Built on Amplify CKLA California’s and Amplify ELA California’s carefully sequenced Knowledge Domains and units, it combines engaging content knowledge with targeted supports and research-based strategies to help students move swiftly toward language proficiency. This program includes:
- Real-world content to provide authentic opportunities to practice reading, writing, speaking, and listening.
- Scaffolding strategies and differentiated instruction to offer targeted support along with five English proficiency levels.
- Progress-monitoring tools to help teachers provide consistent and effective support.
- Teacher Guides that:
- Provide impactful progress monitoring tools including formative and summative assessments and Language Proficiency Assessment rubrics.
- Offer varied differentiation strategies including Support, Challenge, and Access Supports in each lesson segment.
- Are organized into thoughtful lesson segments—Talk Time, Building Background, On Stage and more—that make learning objectives concrete.
- Activities that:
- Expand on domain knowledge from core content and read-alouds and prompt collaborative conversation to practice oral fluency.
- Support hands-on language activities to promote authentic interaction in the classroom.
- Help students bridge experiences and knowledge with images, vocabulary activities, graphic organizers, anticipation guides, writing space, and more.
Category 3: Assessments
Systematic MTSS alignment
In alignment with the additional 2025 Guidance 3.1.a, the assessment systems align with MTSS tiers, including universal screening, diagnostic assessments for students demonstrating a need for additional support, and progress monitoring tools that complement the California’s required universal screening schedule per SB 114.
| Tier 1: Universal/ differentiated support | Tier 2: Supplemental/ targeted support | Tier 3: Intensified/ intensive support | |
| Core instruction assessments Frequency of administration | Amplify CKLA California, Amplify Caminos California, Amplify ELA California assessments Daily, Weekly, Monthly | Amplify CKLA California, Amplify Caminos California, Amplify ELA California assessments Daily, Weekly, Monthly | Amplify CKLA California, Amplify Caminos California, Amplify ELA California assessments Daily, Weekly, Monthly |
| Universal screening assessments Frequency of administration | mCLASS DIBELS and Lectura 3 times per year – BOY, MOY, EOY | mCLASS DIBELS and Lectura 3 times per year – BOY, MOY, EOY | mCLASS DIBELS and Lectura 3 times per year – BOY, MOY, EOY |
| Formal progress monitoring assessments Frequency of administration | mCLASS DIBELS and Lectura 3 times per year – BOY, MOY, EOY | mCLASS DIBELS and Lectura Monthly | mCLASS DIBELS and Lectura Bi-weekly |
| Informal progress monitoring assessments Frequency of administration | Amplify CKLA California, Amplify Caminos California, Amplify ELA California core assessments Daily | Intervention Toolkit progress monitoring assessments When linked to a lesson in the toolkit | Intervention Toolkit progress monitoring assessments When linked to a lesson in the toolkit |
| Diagnostic assessment Frequency of administration | Amplify skill diagnostic assessment Amplify Spanish skill diagnostic assessment Optional after universal screening assessment is administered | Amplify skill diagnostic assessment Amplify Spanish skill diagnostic assessment After universal screening assessment is administered |
Universal assessment system
Amplify’s mCLASS® DIBELS® 8th Edition and mCLASS Lectura are universal and dyslexia screening assessments that should be administered three times per year (BOY, MOY and EOY) to all students. The assessments evaluate student literacy risk, determine progress toward grade-level goals, and indicate the level of instructional support a student may need. Beginning-of-year screenings require adequate instructional time before administration, particularly in grades K–1, while mid-year and end-of-year assessments evaluate instructional effectiveness and guide tier placement adjustments. These screenings also identify students at risk for dyslexia. Universal screening provides essential data for targeting instruction and measuring instructional system effectiveness.
Core instruction assessments
Amplify CKLA California and Amplify ELA California provide a comprehensive suite of assessments for Grades K–8 that range from low-stakes, informal formative assessments to more formal summative assessments. These assessments incorporate a variety of methods and question types, including multiple-choice questions, open-ended questions, and oral and written responses.
Formative assessments:
- Checks for Understanding: Incorporated into each lesson segment throughout daily instruction. Quick pulse-checks that provide immediate feedback during lesson delivery (grades K–5).
- Daily formative assessments: Highlighted moments within each lesson for teachers to plan to track mastery of Primary Focus objectives and standards of each lesson to get a clear snapshot of individual and whole-class progress (grades K–5).
- Activity pages: Completed as part of lessons and can be used to assess lesson content understanding through various formats (grades K–5).
- Exit Tickets: Located at the end of lessons, these provide a quick gauge of students’ ability to meet the lesson’s focus standards (grades 6–8).
- Writing Prompts: Prompts integrated throughout lessons during writing activities that provide skill snapshots within lessons and tracks patterns of skill development over time (grades 6–8).
- Independent reading activities (Solos): At the end of every lesson, students complete an independent reading activity (“solo”) with reading questions that are scored to measure comprehension (grades 6–8).
Summative assessments:
- Skills end-of-unit assessments (grades K–2)
- Knowledge end-of-domain assessments (grades K–2)
- End-of-unit assessments (grades 3–5)
- Unit essays: A culminating end-of-unit set of lessons that guide students through crafting an essay with a rubric to score mastery of writing skills (grades 6–8)
- Unit Reading Assessments: Auto-scored responses and two constructed response items evaluate comprehension, content understanding, and reading skills using the passages students read during the unit (grades 6–8)
Performance Assessments
Student Performance Assessments are multi-day assessments administered in Grades K-5 at the beginning, middle, and end of year to help teachers gauge student mastery of grade-level Core content. These assessments provide critical data to help teachers set targeted instructional goals and monitor individual and class-wide progress towards core objectives.
Progress monitoring
Amplify’s mCLASS® DIBELS® 8th Edition and mCLASS Lectura provide formal progress monitoring in the discrete skills that are indicative of reading growth and predictive of overall success to provide the most instructionally meaningful information to teachers.
Informal progress monitoring tools can be found within the Intervention Toolkit, including materials for teachers to record, track, and evaluate student progress.
Diagnostic assessment
Interventions within Amplify’s literacy programs are informed by a skill diagnostic assessment that provides detailed data on foundational literacy skill deficits. The Amplify Skill Diagnostic Assessment and Amplify Spanish Skill Diagnostic assessment serve as critical tools in this process, administered specifically to students identified as at risk for reading difficulty through universal screening assessments—particularly those demonstrating mCLASS DIBELS 8th Edition or mCLASS Lectura composite scores in the Well Below or Below Benchmark ranges. These diagnostic assessments provide teachers with the precise skills to begin intervention and remediation.
Category 4: Universal Access
Amplify CKLA California and Amplify ELA California were built on the principles of Universal Design for Learning (UDL) and reviewed by CAST, a nonprofit education research and development organization. The program is developed using the Universal Design for Learning framework to proactively ensure that all learners can access and participate in meaningful, challenging learning opportunities.
Universal Design for Learning
The programs incorporate opportunities for engagement, representation, action, and expression based on the guidelines of Universal Design for Learning.
- Multiple Means of Engagement: The programs incorporate interesting and motivating ways for students to interact with information and content. In Amplify CKLA California, the Universal Access section in the introduction of each lesson provides specific lesson-level options based on the needs of individual classrooms and students. Scaffolding for students with various levels of need is incorporated into the design of each lesson.
- Multiple Means of Representation: The programs provide multiple means of presenting content to maximize student understanding. This includes digital component files that allow for a range of presentations of images and text to support learning. Amplify provides access to universal supports such as point-of-use audio for all core texts, embedded definitions for critical vocabulary, and glossaries in multiple languages. Amplify CKLA California includes clarification on language found throughout the program, with sidebars that include support on transition words and syntax, and illustrations to help students understand the concepts they are learning.
- Multiple Means of Action and Expression: The programs include a range of methods for all students, including English Learners, to navigate and demonstrate learning. This includes physical actions, a range of methods for response, appropriate tools for composition, and varied scaffolding. In Amplify ELA California, lessons provide multiple ways for students to interact with text, allowing their brains to process the language through distinct pathways. Activities harness multiple learning modes, using media tools, digital apps, and a variety of visual and physical experiences to strategically support and enhance student learning.
- Accessibility: Universal access features include visual aids, enlarged materials, physical objects, and multiple learning modalities through activities like Push & Say and Wiggle Cards. The Universal Access section in the introduction of each lesson provides specific lesson-level options based on the needs of individual classrooms and students.
Embedded differentiation
Amplify CKLA California and Amplify ELA California provide built-in differentiation strategies in every lesson for all students.
Throughout the Teacher Guides, point-of-use Differentiation icons provide targeted instructional strategies and supports. These icons indicate specific guidance for advanced learners, students who need additional support, and English learners, allowing teachers to easily identify and implement appropriate scaffolds and extensions during instruction. In addition, teachers are provided with recommendations for resources to use with each group of students.
- Pre-teaching supports include mini-lessons on:
- Core vocabulary words
- Core Connections
- Essential Background Information or Terms
- What Have We Already Learned/What Do We Already Know?
- Differentiated Support for Core Instruction tables, located in the overview of each K–2 Skills Teacher Guide, provide a list of specific opportunities for reteaching and additional support in each lesson based on skill.
- Support and Challenge Sidebars in lesson margins offer educators immediate guidance in implementing point-of-use differentiation techniques.
- Flexible Grouping within lessons provides opportunities for teachers to facilitate small groups, partners, or individualized support based on students’ needs. In the Skills Strand, teachers receive specific guidance for differentiated small-group instruction, with targeted support and activities outlined for both Group 1 (students needing additional support) and Group 2 (on-level students) based on data.
- Amplify ELA California provides point-of-use supports embedded within key core lesson activities with six levels of differentiation. The goal of these supports is to fully enable access to grade-level content for all students, including students with disabilities, English learners, and students ready for an additional level of challenge.
- The Universal Access section of Advance Preparation in each lesson includes varied strategies to ensure all students can access and engage in each lesson.
- Frequent use of graphic organizers and visual supports in lessons provide opportunities for differentiation based on need. The program also includes a variety of technological supports, such as eReaders with audio.
- Extension opportunities are suggested throughout lessons, often embedded in writing tasks, which include prompts to use more complex and descriptive vocabulary, figurative language, multi-clause and complex sentences, and informational text characteristics.
Assessment-Driven MTSS resources
- The K–8 Intervention Toolkit is available online and provides easy-to-use resources that assist teachers in filling gaps in students’ reading skills, with activities to support print concepts, phonological awareness, phonics, fluency, and other key skills
- Fluency Packets (Grades 2–5)
- Foundational Skills Intervention Program for Grades 3–8 support students who would benefit from direct and explicit intervention instruction in the full continuum of foundational skills in the upper grades
- Flexible Instructional Time including:
- Pausing Points built into the curriculum that provide teachers with dedicated time to address specific student needs through targeted reteaching, remediation, practice, and extension activities
- Pausing Point activities designed to support English learners’ competence and confidence through differentiated whole-group, small-group, or individual instruction
- Boost Reading is a K–5 student-led digital intervention program. Boost Reading follows Amplify CKLA California’s scope and sequence to reinforce the same foundational skills taught in core instruction. It integrates easily into daily routines, while the robust data provided by mCLASS® DIBELS® 8th Edition offers a detailed view of how students progress across all instructional tiers.
Category 5: Instructional Planning and Teacher Support
Amplify CKLA California and Amplify ELA California teachers are empowered to deliver effective instruction with various print and digital resources. The program provides comprehensive planning and support materials designed to help teachers prepare for and execute lessons effectively and fulfill the requirements of Category 5.
Implementation supports across K–8
Planning and preparation resources
- Unit Overviews that provide important background and context for the texts students will read, including highlighted elements within the text and guidance for how students will work with those elements
- Sub-unit Overviews (Grades 6–8) that provide an overview of Lesson Objectives and reading and writing assignments, as well as a list of any projections, multimedia, or digital apps that can be projected from the teacher’s included digital license
- Lesson-by-lesson preparation checklists (Grades 6–8) accompanying each Sub-unit Overview
- Lesson Briefs for each individual lesson providing important background and context
- Content knowledge materials regarding topics that students will examine
Point-of-use instructional guidance
- Teacher Editions that feature insets of the same text and activity instructions as the corresponding Student Edition, wrapping teacher instruction around these materials
- Activity guidance at point of use
- Lesson standards clearly called out
- Discussion suggestions embedded in lessons
- Differentiation tips at point of use
- Detailed Instructional Guides in each activity that include sequencing and grouping suggestions, tips for facilitating discussion, possible student responses and exemplars
- Student Supports in all core lessons that provide teachers with targeted supports in daily core instruction, addressing which might serve the student best in the moment—support, strengthen, stretch—with additional call-outs for newcomers
Multimedia and digital support
- Teacher tip videos provide modeling and guidance for implementing key foundational skills routines within the program
- Digital platform access where teachers can access printable PDFs of differentiated support materials for English learners and students struggling with reading, including translated Unit Background and Context documents and Text Previews
- Teacher dashboard and reporting tools (Grade 6–8) provide real-time visibility into student progress and work for immediate instructional response
Caregiver supports
Communication and overview resources
- Caregiver Hub available in English and Spanish that provides an overview of the curriculum
- Caregiver Letters for each K–2 Knowledge Domain and unit in Grades 3–5 that provide an overview of the content, the skills students learn, as well as practical methods that continue the learning and knowledge building at home
- Unit-specific Caregiver Letters (Grades 6–8) that provide detailed information regarding what students will read and learn in each unit, including conversation starters that allow caregivers to ask questions and discuss specific aspects of a unit with their student
- Welcome letters that explain the assessment and placement process while inviting parent involvement and offering support
- Editable Home-School Communication letters available in English and Spanish
- Editable Progress Reports for teachers to update parents and guardians on what their child is learning
Content and learning support materials
- Unit Background and Context documents that provide an introduction and overview to the unit’s topic and themes, available in English and Spanish
- Text Previews that provide a brief introduction to formative, independent reading assignments (called Solos in Grades 6–8), available in English and Spanish
- Unit Overview and Support documents (Grades 6–8) designed for caregivers that provide information about important questions, assignments, and key aspects of the unit texts, available in English and Spanish
- Conversation starters included in Knowledge Strand Caregiver Letters to discuss domain topics at home
Home practice and extension activities
- Take-Home pages in the Skills Strand that include copies of decodable passages, enabling students to share their reading progress with families and continue practicing their skills outside of school
- Take-Home Letters in the Skills Strand that provide specific guidance for parents to support skills practice at home, such as sound-sorting activities, with detailed instructions and materials for home practice activities
- Take-Home pages in the Knowledge Strand that provide suggested activities families can do together to reinforce and extend learning beyond the classroom
- Games and activities on take-home pages that extend classroom instruction, including all the materials and instruction necessary to help families assist students in a fun and engaging way
- Digital access to decodable texts through the Amplify Caregiver Hub, allowing students to practice their reading skills both in class and at home
- Weekly spelling lists and directions to decoding activities that can be practiced at home
Welcome, K–8 Program 1 reviewers!
We’re honored to introduce you to Amplify California Language Arts. We’re confident you’ll find this comprehensive program to be a powerful tool for bringing the vision of the California ELA Framework to life in classrooms across the state.
Please start with the video on the right to learn how to navigate the program and access key features referenced within our submission. Below you’ll find additional resources to support your review.
Your review samples
We’re excited for you to begin your review of Amplify Core Knowledge Language Arts (CKLA) California and Amplify ELA California. Physical and digital review materials will vary by grade level.
Reviewer Binders (K–8)
Your physical samples should have arrived in grade-specific boxes with three Reviewer Binders.
- The first binder will contain logistical program review information and the printed Evaluation Criteria Map.
- The second binder will contain the printed Standards Maps for grades K–4.
- The third binder will contain the printed Standards Maps for grades 5–8.
Physical samples (K–5)
You can expect to receive 15 boxes of physical materials for your review. As you begin the process of organizing your materials, please refer to the inventory checklist found inside each box as well as within your Reviewer Binder. Please note you will not receive any physical samples for grades 6–8. Your review of the program for grades 6–8 will be entirely digital.
Digital samples (K–8)
In order to access your digital samples, you’ll need to log in to our platform using your unique login credentials found on a Digital Review Credential flyer inside of your Reviewer Binder. Once you have located the flyer:
- Click the orange button below to access the platform.
- Click “Log in with Amplify.”
- Enter the username and password provided on your Digital Review Credential flyer.
Navigation tips
Before you get started, please review these important functionality notes:
Criteria Map and Standards Maps must be opened on Microsoft Word on your desktop to function as intended. If you open the documents without Microsoft Word on your desktop, citations will be cut off at the bottom of most tables within the document.
Many of our citations are deep-links to PDFs, meaning they will take you to the right page or the first page in the sequence for the citation in question. To ensure this functionality works, please disable any PDF-viewing extensions or plug-ins such as Adobe Acrobat Pro Browser Extension.
[Reviewer program navigation video] Grades K–5
[Reviewer program navigation video] Grades 6–8
Click here for additional information on navigating the digital materials for grades 6–8.
Category 1: English Language Arts (ELA) and English Language Development (ELD) Content/Alignment to Standards
Evaluation Criteria Map
Linked below is the Evaluation Criteria Map for grades K–8. Please note that you will need to be logged into the digital platform to access the links in the Evaluation Criteria Map.
ELA Standards Maps
The links below provide the Standards Maps for Amplify California Core Language Arts for each grade level. Please note that you will need to be logged into the digital platform to access the links in the Standards Maps.
Category 2: Program Organization
The Amplify California Language Arts Program 1 submission includes Amplify CKLA California for Grades K–5 and Amplify ELA California for Grades 6–8. This comprehensive curriculum provides a full year of evidence-based instruction for each grade level, transitioning from foundational literacy to advanced text analysis.
Program structure
Amplify’s California Language Arts programs are built on what the research shows: Strong readers need both word recognition and language comprehension. Our comprehensive curriculum suite follows the Simple View of Reading and The Reading Rope–bringing together foundational skills and knowledge building to deliver instruction grounded in evidence-based literacy practices.
Each lesson follows a predictable structure with clearly marked components, beginning with warm-up routines, progressing through explicit instruction with guided practice, and concluding with independent application activities. The program provides detailed teacher language, including question stems and discussion prompts, ensuring clear and consistent delivery of instruction.
[Reviewer highlight video] Program organization for Category 2
[Reviewer highlight video] Program structure for grades K–2
[Reviewer highlight video] Program structure for grades 3–5
[Reviewer highlight video] Program structure for grades 6–8
Amplify CKLA California empowers teachers to deliver effective instruction and keeps students engaged with the following resources:
- Teacher Guides
- Assessment Guides
- Authentic texts and trade books
- Knowledge Image Cards
- Knowledge Flip Books
- Remediation and intervention resources
- Decodable readers
- Student Readers and novels
- Student Activity Books
- Poet’s Journals
- eReaders
- Sound Library featuring articulation videos and songs
- Instructional routine modeling videos
- Assignable Practice Games
- On-demand professional development
Amplify ELA California students stay engaged with the following resources:
- Teacher Guides that include:
- Detailed lesson plans
- Standards alignment and exit tickets
- Real-time differentiation strategies
- Robust reporting
- Student Editions that include:
- High-quality narrative and informational texts
- Videos, audio supports, and digital experiences that capture their attention
- Personal Writing Journal to keep all student writing in one place
- Trade Books
Core literacy philosophy
Support every learner. Meet all learning needs with a Multi-Tiered System of Supports (MTSS) that brings together universal screening, scaffolded core instruction, support for English learners, and data-driven intervention to ensure every student gets what they need to succeed.
Deliver consistent foundational skills instruction. Daily explicit, systematic skills instruction in grades K–2, with targeted yet flexible support for students still building decoding confidence in grades 3–8, ensures mastery of essential reading foundations.
Build lasting knowledge across all grades. Through coherently sequenced, content-rich instruction that revisits key vocabulary and concepts with increasing complexity, students build meaningful connections that deepen their vocabulary and reading comprehension.
Strengthen reading through writing at every level. Regular writing instruction grounded in the Science of Writing supports reading comprehension, improves sentence-level writing, and provides the foundation for high-quality composition. As students progress through the upper grades, they engage in increasingly complex analytical tasks—synthesizing ideas, drawing generalizations, and interpreting multiple textual layers through both focused quick-writes and comprehensive essays.
Foster oral language development. Structured opportunities for academic conversation and evidence-based dialogue build students’ ability to express complex ideas with precision and allow them to participate confidently in classroom discussions.
Measure growth with comprehensive assessments. Assessments range from in-the-moment checks for understanding to summative assessments that measure progress toward skills mastery and standards proficiency, providing the data needed to drive targeted instruction.
Scope and sequence
Below you can view the scope and sequence for each grade level.
Routines
Amplify CKLA California and Amplify ELA California include several structured instructional routines that provide predictable patterns for both teachers and students:
Discussion and collaboration routines:
- Turn and Talk: Partners discuss text-specific content using sentence starters and frames
- Think-Pair-Share: Students engage in individual thinking, partner discussion, and whole-class sharing
- Partner reading: Students sit shoulder-to-shoulder, taking turns reading and listening
Foundational Skills routines:
- Sound-spelling review: Warm-up activities that reinforce phonics patterns
- Oral blending warm-ups: Teacher-guided practice progressing to independent application
- Finger tapping: Techniques for blending sounds
- Chaining activities: Students manipulate letters to transform one word into another
- Word Work: Daily short activities focused on domain-specific and academic vocabulary
Knowledge-building routines:
- Vocabulary preview: Introduction of new words before reading
- Read-aloud procedures: Established routines for introducing and discussing complex texts
- Text discussions: Structured comprehension conversations with scaffolded questioning
Fluency routines:
- Teacher modeling: Demonstration of proper intonation, expression, and pacing
- Choral reading: Whole-class reading practice
- Partner reading: Paired fluency practice
Close reading routines
The program includes carefully structured close reading activities that guide students through multiple encounters with complex texts. These routines help students develop deeper comprehension through systematic analysis and discussion.
Each routine includes comprehensive instructional guides with clear-cut directions for implementation, straightforward explanations of concepts, and suggestions for discussion.
Category 3: Assessments
Systematic MTSS alignment
In alignment with the additional 2025 Guidance 3.1.a, the assessment systems align with MTSS tiers, including universal screening, diagnostic assessments for students demonstrating a need for additional support, and progress monitoring tools that complement California’s required universal screening schedule per SB 114.
| Tier 1: Universal/ differentiated support | Tier 2: Supplemental/ targeted support | Tier 3: Intensified/ intensive support | |
| Core instruction assessments Frequency of administration | Amplify CKLA California, Amplify ELA California assessments Daily, Weekly, Monthly | Amplify CKLA California, Amplify ELA California assessments Daily, Weekly, Monthly | Amplify CKLA California, Amplify ELA California assessments Daily, Weekly, Monthly |
| Universal screening assessments Frequency of administration | mCLASS DIBELS and mCLASS Lectura 3 times per year – BOY, MOY, EOY | mCLASS DIBELS and mCLASS Lectura 3 times per year – BOY, MOY, EOY | mCLASS DIBELS and mCLASS Lectura 3 times per year – BOY, MOY, EOY |
| Formal progress monitoring assessments Frequency of administration | mCLASS DIBELS and mCLASS Lectura 3 times per year – BOY, MOY, EOY | mCLASS DIBELS and mCLASS Lectura Monthly | mCLASS DIBELS and mCLASS Lectura Bi-weekly |
| Informal progress monitoring assessments Frequency of administration | Amplify CKLA California, Amplify ELA California core assessments Daily | Intervention Toolkit progress monitoring assessments When linked to a lesson in the toolkit | Intervention Toolkit progress monitoring assessments When linked to a lesson in the toolkit |
| Diagnostic assessment Frequency of administration | Amplify skill diagnostic assessment Optional after universal screening assessment is administered | Amplify skill diagnostic assessment After universal screening assessment is administered |
Universal assessment system
Amplify’s mCLASS® DIBELS® 8th Edition (K–8) and mCLASS Lectura (K–6) are universal and dyslexia screening assessments that should be administered three times per year (BOY, MOY and EOY) to all students. The assessments evaluate student literacy risk, determine progress toward grade-level goals, and indicate the level of instructional support a student may need. Beginning-of-year screenings require adequate instructional time before administration, particularly in grades K–1, while mid-year and end-of-year assessments evaluate instructional effectiveness and guide tier placement adjustments. These screenings also identify students at risk for dyslexia. Universal screening provides essential data for targeting instruction and measuring instructional system effectiveness.
Core instruction assessments
Amplify CKLA California and Amplify ELA California provide a comprehensive suite of assessments for Grades K–8 that range from low-stakes, informal formative assessments to more formal summative assessments. These assessments incorporate a variety of methods and question types, including multiple-choice questions, open-ended questions, and oral and written responses.
Formative assessments:
- Checks for Understanding: Incorporated into each lesson segment throughout daily instruction. Quick pulse-checks that provide immediate feedback during lesson delivery (grades K–5).
- Daily formative assessments: Highlighted moments within each lesson for teachers to plan to track mastery of Primary Focus objectives and standards of each lesson to get a clear snapshot of individual and whole-class progress (grades K–5).
- Activity pages: Completed as part of lessons and can be used to assess lesson content understanding through various formats (grades K–5).
- Exit Tickets: Located at the end of lessons, these provide a quick gauge of students’ ability to meet the lesson’s focus standards (grades 6–8).
- Writing Prompts: Prompts integrated throughout lessons during writing activities that provide skill snapshots within lessons and tracks patterns of skill development over time (grades 6–8).
- Independent reading activities (Solos): At the end of every lesson, students complete an independent reading activity (“Solo”) with reading questions that are scored to measure comprehension (grades 6–8).
Summative assessments:
- Skills end-of-unit assessments (grades K–2)
- Knowledge end-of-domain assessments (grades K–2)
- End-of-unit assessments (grades 3–5)
- Unit essays: A culminating end-of-unit set of lessons that guide students through crafting an essay with a rubric to score mastery of writing skills (grades 6–8)
- Unit Reading Assessments: Auto-scored responses and two constructed response items evaluate comprehension, content understanding, and reading skills using the passages students read during the unit (grades 6–8)
Performance Assessments
Student Performance Assessments are multi-day assessments administered in Grades K–5 at the beginning, middle, and end of year to help teachers gauge student mastery of grade-level Core content. These assessments provide critical data to help teachers set targeted instructional goals and monitor individual and class-wide progress towards core objectives.
Progress monitoring
Amplify’s mCLASS® DIBELS® 8th Edition and mCLASS Lectura provide formal progress monitoring in the discrete skills that are indicative of reading growth and predictive of overall success to provide the most instructionally meaningful information to teachers.
Informal progress monitoring tools can be found within the Intervention Toolkit, including materials for teachers to record, track, and evaluate student progress.
Diagnostic assessment
Interventions within Amplify’s literacy programs are informed by a skill diagnostic assessment that provides detailed data on foundational literacy skill deficits. The Amplify Skill Diagnostic Assessment and Amplify Spanish Skill Diagnostic assessment serve as critical tools in this process, administered specifically to students identified as at risk for reading difficulty through universal screening assessments—particularly those demonstrating mCLASS DIBELS 8th Edition or mCLASS Lectura composite scores in the Well Below or Below Benchmark ranges. These diagnostic assessments provide teachers with the precise skills to begin intervention and remediation.
Category 4: Universal Access
Amplify CKLA California and Amplify ELA California were built on the principles of Universal Design for Learning (UDL) and reviewed by CAST, a nonprofit education research and development organization. The program is developed using the Universal Design for Learning framework to proactively ensure that all learners can access and participate in meaningful, challenging learning opportunities.
Universal Design for Learning
The programs incorporate opportunities for engagement, representation, action, and expression based on the guidelines of Universal Design for Learning.
- Multiple Means of Engagement: The programs incorporate interesting and motivating ways for students to interact with information and content. In Amplify CKLA California, the Universal Access section in the introduction of each lesson provides specific lesson-level options based on the needs of individual classrooms and students. Scaffolding for students with various levels of need is incorporated into the design of each lesson.
- Multiple Means of Representation: The programs provide multiple means of presenting content to maximize student understanding. This includes digital component files that allow for a range of presentations of images and text to support learning. Amplify provides access to universal supports such as point-of-use audio for all core texts, embedded definitions for critical vocabulary, and glossaries in multiple languages. Amplify CKLA California includes clarification on language found throughout the program, with sidebars that include support on transition words and syntax, and illustrations to help students understand the concepts they are learning.
- Multiple Means of Action and Expression: The programs include a range of methods for all students, including English learners, to navigate and demonstrate learning. This includes physical actions, a range of methods for response, appropriate tools for composition, and varied scaffolding. In Amplify ELA California, lessons provide multiple ways for students to interact with text, allowing their brains to process the language through distinct pathways. Activities harness multiple learning modes, using media tools, digital apps, and a variety of visual and physical experiences to strategically support and enhance student learning.
- Accessibility: Universal access features include visual aids, enlarged materials, physical objects, and multiple learning modalities through activities like Push & Say and Wiggle Cards. The Universal Access section in the introduction of each lesson provides specific lesson-level options based on the needs of individual classrooms and students.
Embedded differentiation
Amplify CKLA California and Amplify ELA California provide built-in differentiation strategies in every lesson for all students.
- Pre-teaching supports include mini-lessons on:
- Core vocabulary building
- Core connections
- Essential background information building
- What Have We Already Learned?/What Do We Already Know?
- Differentiated Support for Core Instruction tables, located in the overview of each K–2 Skills Teacher Guide, provide a list of specific opportunities for reteaching and additional support in each lesson based on skill.
- Support and Challenge Sidebars in lesson margins offer educators immediate guidance in implementing point-of-use differentiation techniques.
- Flexible Grouping within lessons provides opportunities for teachers to facilitate small groups, partners, or individualized support based on students’ needs. In the Skills Strand, teachers receive specific guidance for differentiated small-group instruction, with targeted support and activities outlined for both Group 1 (students needing additional support) and Group 2 (on-level students) based on data.
- Amplify ELA California provides point-of-use supports embedded within key core lesson activities with six levels of differentiation. The goal of these supports is to fully enable access to grade-level content for all students, including students with disabilities, English learners, and students ready for an additional level of challenge.
- The Universal Access section of Advance Preparation in each lesson includes varied strategies to ensure all students can access and engage in each lesson.
- Frequent use of graphic organizers and visual supports in lessons provide opportunities for differentiation based on need. The program also includes a variety of technological supports, such as eReaders with audio.
- Extension opportunities are suggested throughout lessons, often embedded in writing tasks, which include prompts to use more complex and descriptive vocabulary, figurative language, multi-clause and complex sentences, and informational text characteristics.
Assessment-driven MTSS resources
- The K–8 Intervention Toolkit is available online and provides easy-to-use resources that assist teachers in filling gaps in students’ reading skills, with activities to support print concepts, phonological awareness, phonics, fluency, and other key skills
- Fluency Packets (Grades 2–5)
- Foundational Skills Intervention Program for Grades 3–8 support students who would benefit from direct and explicit intervention instruction in the full continuum of foundational skills in the upper grades
- Flexible Instructional Time including:
- Pausing Points built into the curriculum that provide teachers with dedicated time to address specific student needs through targeted reteaching, remediation, practice, and extension activities
- Pausing Point activities designed to support English learners’ competence and confidence through differentiated whole-group, small-group, or individual instruction
- Boost Reading is a K–5 student-led digital intervention program. Boost Reading follows Amplify CKLA California’s scope and sequence to reinforce the same foundational skills taught in core instruction. It integrates easily into daily routines, while the robust data provided by mCLASS® DIBELS® 8th Edition offers a detailed view of how students progress across all instructional tiers.
Category 5: Instructional Planning and Teacher Support
Amplify CKLA California and Amplify ELA California teachers are empowered to deliver effective instruction with various print and digital resources. The program provides comprehensive planning and support materials designed to help teachers prepare for and execute lessons effectively and fulfill the requirements of Category 5.
Implementation supports across K–8
Planning and preparation resources
- Unit Overviews that provide important background and context for the texts students will read, including highlighted elements within the text and guidance for how students will work with those elements
- Sub-unit Overviews (Grades 6–8) that provide an overview of Lesson Objectives and reading and writing assignments, as well as a list of any projections, multimedia, or digital apps that can be projected from the teacher’s included digital license
- Lesson-by-lesson preparation checklists (Grades 6–8) accompanying each Sub-unit Overview
- Lesson Briefs for each individual lesson providing important background and context
- Content knowledge materials regarding topics that students will examine
Point-of-use instructional guidance
- Teacher Editions that feature insets of the same text and activity instructions as the corresponding Student Edition, wrapping teacher instruction around these materials
- Activity guidance at point of use
- Lesson standards clearly called out
- Discussion suggestions embedded in lessons
- Differentiation tips at point of use
- Detailed Instructional Guides in each activity that include sequencing and grouping suggestions, tips for facilitating discussion, possible student responses and exemplars
- Student Supports in all core lessons provide teachers with targeted supports in daily core instruction, addressing which might serve the student best in the moment—support, strengthen, stretch—with additional call-outs for newcomers
Multimedia and digital support
- Teacher tip videos provide modeling and guidance for implementing key foundational skills routines within the program
- Digital platform access where teachers can access printable PDFs of differentiated support materials for English learners and readers struggling with text, including translated Unit Background and Context Documents and Text Previews
- Teacher Dashboard and reporting tools (Grade 6–8) that provide real-time visibility into student progress and work for immediate instructional response
Caregiver supports
Communication and overview resources
- Caregiver Hub available in English and Spanish that provides an overview of the curriculum
- Caregiver Letters for each K–2 Knowledge Domain and unit in Grades 3–5 that provide an overview of the content, the skills students learn, as well as practical methods that continue the learning and knowledge building at home
- Unit-specific Caregiver Letters (Grades 6–8) that provide detailed information regarding what students will read and learn in each unit, including conversation starters that allow caregivers to ask questions and discuss specific aspects of a unit with their student
- Welcome letters that explain the assessment and placement process while inviting parent involvement and offering support
- Editable Home-School Communication letters available in English and Spanish
- Editable Progress Reports for teachers to update parents and guardians on what their child is learning
Content and learning support materials
- Unit Background and Context documents that provide an introduction and overview to the unit’s topic and themes, available in English and Spanish
- Text Previews that provide a brief introduction to formative, independent reading assignments (called Solos in Grades 6–8), available in English and Spanish
- Unit Overview and Support documents (Grades 6–8) designed for caregivers that provide information about important questions, assignments, and key aspects of the unit texts, available in English and Spanish
- Conversation starters included in Knowledge Strand Caregiver Letters to discuss domain topics at home
Home practice and extension activities
- Take-Home pages in the Skills Strand that include copies of decodable passages, enabling students to share their reading progress with families and continue practicing their skills outside of school
- Take-Home Letters in the Skills Strand that provide specific guidance for parents to support skills practice at home, such as sound-sorting activities, with detailed instructions and materials for home practice activities
- Take-Home pages in the Knowledge Strand that provide suggested activities families can do together to reinforce and extend learning beyond the classroom
- Games and activities on Take-Home Pages that extend classroom instruction, including all the materials and instruction necessary to help families assist students in a fun and engaging way
- Digital access to decodable texts through the Amplify Caregiver Hub, allowing students to practice their reading skills both in class and at home
- Weekly spelling lists and directions to decoding activities that can be practiced at home
Making reading comprehension connections
Comprehension isn’t just a process, or just a product—it’s both. And connecting reading and understanding is what most teachers are working on every day.
That fundamental connection was the focus of our recent Science of Reading Webinar Week: Comprehension Connections—Building the Bridge Between Reading and Understanding, a five-day, expert-filled series that unpacked what really drives comprehension, from early decoding to middle school mastery.
Here’s a quick look at what you’ll learn when you watch—and a few ideas you can use right away.
Day 1: What Is Reading Comprehension, Anyway?
Speaker: Susan Lambert, Ed.D., Chief Academic Officer, Literacy, Amplify; Host of Science of Reading: The Podcast
“Reading comprehension is more than just language comprehension. It’s language comprehension on the page, which makes it much more complex.” — Susan Lambert, Ed.D.
If you ask ten teachers to define comprehension, you might get twelve answers. Lambert opened the week by grounding everyone in the Science of Reading, including the Simple View of Reading and the Reading Rope. Skilled reading, she reminded viewers, is the result of multiple strands—decoding, language comprehension, and knowledge—woven together over time.
The takeaway? The most effective approaches don’t teach comprehension strategies—such as “find the main idea”—in isolation. Rather, they connect word recognition to meaning through rich texts, conversation, and writing. Whether you’re teaching second-grade reading comprehension or sixth-grade reading comprehension, students need the same thing: a clear path from sounding out words to making sense of ideas.
Day 2: Comprehension and Knowledge Building: A Two-Way Street
Speakers: Sonia Cabell, Ph.D., Sigmon Endowed Professor of Reading Education, Florida State University
HyeJin Hwang, Ph.D., Assistant Professor, Department of Educational Psychology, University of Minnesota Twin Cities
“Better background knowledge leads to improved reading comprehension, which in turn enables readers to learn more from text, thereby building additional knowledge.” —HyeJin Hwang, Ph.D.
In their session, Sonia Cabell and HyeJin Hwang explored one of the clearest findings in reading research: Comprehension and knowledge develop together. Cabell began by explaining how comprehension (including oral language, background knowledge, vocabulary, syntax, and verbal reasoning) forms one of the essential strands of the Reading Rope.
Students can’t activate knowledge they don’t yet have. Teachers need to help them build it early, and intentionally. Cabell’s research found that integrating literacy and content instruction produced gains in vocabulary and content knowledge.
Likewise, Hwang’s two large-scale longitudinal studies showed that better knowledge instruction leads to better reading, which leads to even more knowledge. These findings held true across languages and grade levels, underscoring the universal value of content-rich instruction.
Classroom takeaways:
- Plan literacy units around connected science or social studies topics to build coherent knowledge.
- Use content-rich interactive read-alouds with discussion before, during, and after reading.
- Ask inferential comprehension questions (“Why?” “How?”) that require students to connect ideas using their own words.
- Encourage quick writing or drawing tasks that help students show what they’ve learned.
Day 3: Where and How to Measure Comprehension to Drive Improvement
Speakers: Danielle Damico, Ph.D., Executive Director of Learning Science, Amplify
Gina Biancarosa, Ed.D., Ann Swindells Chair in Education, University of Oregon
“Reading comprehension is both a process and a product.” —Danielle Damico, Ph.D.
Too often, comprehension is measured only as a finished product—how well students answer questions after reading—without revealing how they built understanding along the way. This session explored what comprehension actually involves: reading words accurately, understanding their meaning, applying background knowledge, and making inferences. As researcher Sharon Vaughn, Ph.D., has described, these interconnected skills all work together as students learn to read.
Biancarosa showed how looking at comprehension as a complex process helps teachers see student thinking in action. She described the major types of inferences—lexical, bridging, gap-filling, and causal—and the importance of understanding how students connect ideas and construct meaning.
Try this:
- Treat comprehension as ongoing thinking, not a one-time test score.
- Use brief think-alouds or class discussions to get a look at how students connect ideas.
- Match assessments to the precise question you’re trying to answer.
- Let assessment guide instruction—data should lead directly to next steps.
Day 4: Comprehension in Middle School: More Important Than Ever
Speaker: Deb Sabin, Chief Academic Officer, Amplify ELA
“Writing done right encodes knowledge. And discourse done right gets into the realm of higher-order thinking.” —Deb Sabin
By the time you’re teaching fourth-grade reading comprehension through sixth-grade reading comprehension, decoding should be automatic. At this stage, the upper strands of the Reading Rope—vocabulary, background knowledge, and syntax—move to the forefront. In this session, Deb Sabin highlighted how comprehension in middle school relies on academic knowledge, disciplinary vocabulary, and structured discourse—and how it truly blossoms when reading, writing, and speaking reinforce one another.
Classroom moves that help:
- Pair writing with reading: Even short, text-based responses consolidate knowledge in long-term memory.
- Use structured discussion (“accountable talk”), where students cite text evidence and build on one another’s ideas.
- Center rich, grade-level texts that challenge thinking and vocabulary.
Day 5: Finding the Missing Link in Reading Comprehension to Boost Literacy Success
Speaker: Julie A. Van Dyke, Ph.D., Clinical Assistant Professor, Yale University Child Study Center; Research Scientist, Yale-UConn Haskins Global Literacy Hub
“Teach phonics for decoding. Teach syntax for understanding.” —Julie A. Van Dyke, Ph.D.
In the final presentation of the series, Julie Van Dyke explored an often-overlooked element of comprehension: syntax—the way words combine to create meaning. Van Dyke argued that syntax is to comprehension what phonics is to decoding.
She illustrated how the Science of Reading and the Reading Rope locate syntax within the language-comprehension strands—critical to understanding who did what to whom in complex sentences. Explicitly teaching sentence structure helps all learners, including multilingual/English learners, access higher-level meaning.
Simple practices can make a difference:
- Have students paraphrase tricky sentences. (Starter question: “Who’s doing the action?”)
- Pull strong sentences from your class texts to show how structure shapes meaning.
- Encourage students to mirror those structures in their own writing.
What linked all five sessions together? The understanding that comprehension develops when teachers connect the code, the language, and the knowledge. Whether students are decoding in second grade or crafting essays in sixth, they thrive when we help them move from reading to understanding—step by step, strand by strand.
Watch all five on-demand recordings.
More to explore:
- Download your Comprehension 101 bundle.
- Read (and comprehend!): Reading comprehension strategies grounded in science
- Listen to this special Essentials episode of Science of Reading: The Podcast, where Susan Lambert and other experts distill key reading comprehension insights.
A powerful partnership
Amplify Science was developed by the science education experts at UC Berkeley’s Lawrence Hall of Science and the digital learning team at Amplify.
Back to school 2020–21 updates
Back to school 2020 is coming! Click here for more information on all of the improvements and new features we’re adding to Amplify Science for the new school year.
Program introduction
Onboarding: what to expect
Welcome to Amplify Science! To help you know what’s coming next, we created the following outline of the steps of the onboarding process. You can use it as a reference.
Administrators receive launch email
- Share the information with teachers
- Submit the shipping survey sent to your email
Log In
- Go to learning.amplify.com
- Click on Log in with Clever or Google
- Enter your FCPS credentials
- Demo Account for full access to Amplify Curriculum without access to personalized class rosters:
- Go to learning.amplify.com
- Click on login with Amplify
- Username: t.Fayette2020@tryamplify.net
- Password: AmplifyNumber1
Ensure you have received all materials and components
- Teachers have access to a series of “Unboxing your materials kit” videos. If you’re interested in watching those, click here.
Check out the professional learning opportunities and/or access the Getting Started Resources below.
If you need assistance, please see the help resources or reach out to your Educational Partnerships Manager or PD manager at caffleck@amplify.com, pworks@amplify.com with any questions.
K–5 resources
To ensure your first day using Amplify Science in the classroom is as seamless and smooth as possible, we recommend reviewing the following checklist before the first day of school.
What’s coming to my school?
Each unit of Amplify Science comes with a hands-on materials kit. Each hands-on materials kit arrives in one to three boxes and contains:
- Consumable materials for two uses of 25 or 36 students (depending on school purchase)
- Non-consumable materials
- Classroom wall materials
- Premium print materials (card sorts, vocabulary rings, etc.).
- 18 copies of each Student Book (5 titles each unit, K–1 will receive 5 big books per unit)
- A blackline master of the Student Investigation Notebook
You can find complete materials lists for each unit in the following PDF. This information is also available in the digital Teacher’s Guide within the program.
Onboarding videos
Our team has created a series of short videos to help get you started with Amplify Science:
What’s online?
Planning strategies
How to log in and navigate
NGSS introduction
Planning guides
As you prepare to plan for a unit, download our planning guides to help walk you through the most important resources to locate in either the print or digital Teacher’s Guide to help you plan:
Additional resources
If you’re interested in learning more about each unit’s anchor phenomena, the Student Books in each unit, and more program features, download the resources below:
- Guided tour
- Spanish-language supports in grades K–5
- Phenomena in grades K–5
- Student Books in grades K–5
- Simulations in grades 4–8
- Scope and Sequence
Learning to read is not innate. It needs to be taught intentionally and systematically—and science tells us how. The vast and growing body of research on early literacy is referred to as the Science of Reading. It draws on extensive research in cognitive science, linguistics, and neuroscience. It emphasizes the systematic teaching of foundational skills—such as phonics, phonological awareness, and decoding—in building vocabulary and comprehension. In other words, it deconstructs the processes behind how children learn to read, and provides evidence for the instructional practices and early literacy resources that can get them there.
The Science of Reading refers to the pedagogy and practices proven by extensive research to effectively teach children how to read. It places a strong emphasis on both components of the Simple View of Reading, demonstrating that systematic and explicit instruction in phonics and and intentionally sequenced knowledge building are critical to reading success.
In a balanced literacy environment, learning happens through reading and writing immersion, where the need for explicit instruction in phonics is recognized but is not the primary focus.
The key difference between the approaches lies in their emphasis on foundational reading skills and a coherent approach to building language comprehension.
A balanced literacy approach typically includes a combination of whole language approaches (emphasizing meaning and context) and phonics instruction. Balanced literacy instruction is designed to be flexible and open to interpretation by the instructor. It may include the three-cueing system, which encourages students to rely on syntactic and semantic clues in a text to read an unfamiliar word, rather than decoding (Does it look right? Does it sound right? Does it make sense?). Balanced literacy practitioners may also use leveled reading to differentiate instruction, which can can limit vocabulary exposure, hinder in-depth comprehension skills, and further widen achievement gaps.
Balanced literacy has long been a popular approach to reading instruction, with educators appreciating its openness to variation. But advocates for the Science of Reading argue that an evidence-based approach aligned with known cognitive processes and a focus on foundational skills and language comprehension provides the most solid foundation for reading instruction—for confident and struggling readers alike.
According to our friends at The Reading League, the Science of Reading is important not because it gives us an effective way to teach reading, but because it gives us the most effective way to teach reading.
“The Science of Reading is critical because it emphasizes evidence-based instruction. Decades of scientific research on reading have consistently shown the most effective ways to teach reading. The Science of Reading incorporates this research, which includes phonemic awareness, phonics, fluency, vocabulary, and comprehension.”
The Reading League also takes it to the next level: What happens when all children have access to the most effective early literacy and reading education? “We believe in a future where a collective focus on applying the Science of Reading through teacher and leader preparation, classroom application, and community engagement will elevate and transform every community, every nation, through the power of literacy.”
The Science of Reading has identified five foundational reading skills that are considered crucial for early reading development. One of those skills is phonics. In other words, the Science of Reading has established that phonics are crucial, but the Science of Reading is not the same as phonics.
Phonics instruction helps students learn how to sound out and blend letters to read words accurately. As we know from the Simple View of Reading, two fundamental skills are required for reading with comprehension:
- Decoding—the ability to recognize written words (via phonics)
- Language comprehension—understanding what words mean
And the Science of Reading also reminds us that students do not have to learn phonics or decoding before knowledge comes into the equation. “The background knowledge that children bring to a text is also a contributor to language comprehension,” says Sonia Cabell, Ph.D., associate professor at Florida State University’s School of Teacher Education, on Science of Reading: The Podcast.
The Science of Reading is an evolving field built on decades of high-quality, evidence-based research that continually integrates new insights gathered from cognitive neuroscience, psychology, and linguistics. These ongoing studies constantly refine our understanding of how the human brain processes language and learning, enabling more personalized and effective teaching strategies that can adapt to the wide-ranging learning needs of students.
Like other sciences such as medicine, astronomy, or engineering – new advancements in reading technology allow us to understand how the brain works and refine our practices. Every scientific advancement in this field of reading science deepens our comprehension of reading-related challenges like dyslexia and informs the development of evidence-based interventions. We don’t believe that the Science of Reading can be reduced to a fad or trend. Rather, it is a continually evolving, enduringly effective discipline, grounded in rigorous research and driven by the quest for better comprehension of how we read and learn.
Assessment grounded in the Science of Reading can help identify children at risk of dyslexia at the earliest possible moments, creating the widest opportunity for intervention.
People with dyslexia often experience challenges in phonological awareness. They may struggle to break down words into their component sounds and to recognize the relationships between letters and sounds. Systematic and explicit instruction in phonics and phonological awareness can help individuals with dyslexia develop necessary phonological skills. This evidence-based instruction can also help students who have difficulty with decoding.
Further, evidence-based comprehension instruction, including explicit instruction in vocabulary and comprehension strategies, can support students with dyslexia in understanding and making meaning from text.
The Science of Reading can be integrated with a Multi-Tiered System of Supports (MTSS) to provide comprehensive and targeted reading instruction for all students. The Science of Reading aligns with a tiered model by providing evidence-based practices for instruction at each tier. An MTSS includes universal screening to identify students at risk of reading difficulties; the Science of Reading can also guide the selection of screening measures to assess specific foundational skills. Aligning the Science of Reading with an MTSS framework can also enhance instructional practices and interventions, ensure data-driven decision making, and help meet the needs of all students.
Integrating the Science of Reading and the Science of Writing strengthens our approach to teaching literacy. Reading and writing are interdependent. Understanding how sentences are built not only contributes to better reading comprehension, it also helps writers develop clear, logical text. As students grow as readers, they also grow as writers, leading to a comprehensive literacy education. Clear thinking and effective writing are crucial for expressing ideas. By fostering both skills, teachers better support students in becoming confident readers and writers, prepared for academic challenges and beyond.
One of the research-based frameworks used in the Science of Reading is the Simple View of Reading. According to the Simple View, two cognitive capacities are needed for proficient reading: (1) understanding the language (comprehension) and (2) recognizing words in print (decoding). A true Science of Reading program is designed from the start for students to build these skills, in a developmentally appropriate way.
It will also emphasize the importance of knowledge building by exposing students to a diverse array of new topics spanning history, science, and literature, organized intentionally and coherently within and across grades. Deep and intentionally sequenced knowledge domains will help build a student’s vocabulary and understanding of complex texts. And it will include instruction in all five foundational skills: phonics, phonemic awareness, vocabulary, fluency, and comprehension.
Download our free ebook, Science of Reading: Making the Shift, which includes a checklist of what to look for in a curriculum based on the Science of Reading. Learn more from our friends at The Reading League.
Actually, we have a full literacy suite built on the Science of Reading! It includes:
- mCLASS® assessment, powered by DIBELS® 8th Edition, a gold-standard universal and dyslexia screener, plus a progress monitoring tool, all in one.
- Amplify Core Knowledge Language Arts (CKLA), which provides explicit, systematic foundational skills instruction combined with intentional knowledge building.
- Boost Reading, a highly adaptive personalized reading program that reinforces the core curriculum and supports enrichment, remediation, and intervention for each student in your classroom.
- mCLASS Intervention, a staff-led intervention program targeted to Tiers 2 and 3, made easy with automatic data-driven grouping and sequenced explicit, systematic skills lesson plans to support at-risk students.
Reading requires deliberate, systematic attention—and so does shifting to the Science of Reading in your school or district. It requires not only the right curriculum, but also all-new mindsets, metrics, and more. Reflecting years of experience supporting real educators, our resources will walk you through the process of change management in your community—and show you why the shift is worth it. View our Science of Reading change management playbook.
Exciting updates are coming for Boost Reading!
Amplify Customer Experience Hiring
S1-04: Connecting with students and caregivers in the science classroom: Ryan Rudkin
In this special episode, our host Eric Cross sits down with veteran middle school teacher Ryan Rudkin. Ryan shares her expertise after almost two decades in the classroom, discussing ways to incorporate aspects of problem-based learning into the K–8 science classroom. Eric and Ryan talk about how to increase parent engagement, involve community members, and add excitement to lessons.
Explore more from Science Connections by visiting our main page.
Ryan Renee Rudkin (00:00):
I know there’s other goals in mind, you know, standards and test scores. But at the end of the day, I wanna come back and I want them to come back.
Eric Cross (00:35):
My name’s Eric Cross, host of our science podcast, and I am with Ryan Rudkin, middle-school teacher out here in California just to the north up near Sacramento? El Dorado Hills?
Ryan Renee Rudkin (00:46):
Yeah. 20 miles east of Sacramento.
Eric Cross (00:49):
Nice. And I am down here in San Diego. And so Ryan, to start off, what I wanna do is ask you about your origin story, like a superhero. So how did you become a middle-school science teacher to become part of this elite profession of science folks that get to do awesome things with kids?
Ryan Renee Rudkin (01:08):
I would agree with you that it is definitely an elite profession. I got my credential and I thought I was gonna teach third or fourth grade elementary school. And the second day I got called for a sub job for middle school. And I just thought, “We’ll take it,” you know? And by second period, I knew: This is where I belong. The kids, middle school, students are just a species of their own. And you have to appreciate them. And if you do appreciate them, then you’re in the right spot. And I quickly looked at my coursework and I was able to get authorizations in science, history, and English, and I love science. So I chose science. And the rest is history. It’s been a wild ride and I wouldn’t have changed or asked for anything different. I love it.
Eric Cross (02:02):
I definitely agree with you. So, your history—you’ve been in various middle-school classrooms. Can you tell us a little bit about that? What classrooms have you been in? What disciplines of science have you taught or are currently teaching?
Ryan Renee Rudkin (02:14):
I was hired for seventh grade life science, and then I did that for a few years and then I got moved into eighth physical science, and I was there for 12 years. Love eighth grade science. I love eighth graders. Chemistry and physics are my favorite. There’s just so much opportunity for just awesome labs, great conversations, student discourse, all of that. And then the past three years I’ve been in sixth grade and now we’re integrated. So,a sixth grade integrated science and I also teach social studies and a technology design class.
Eric Cross (02:52):
Oh, nice. What do you do in your technology design class? That sounds cool.
Ryan Renee Rudkin (02:56):
Right now it’s mostly internet media and we use WeVideo, it’s an editing-video program, and we produce and put on our school weekly news bulletin. And then we weave in other projects. We do some interdisciplinary projects. Right now my students are working on a mythology God, Goddess, and Monster project that relates to our social studies curriculum. And we’re learning about Greece. So yeah, we just try to give them added projects and they’re using the WeVideo platform. By sixth grade, they’re coming to us now with wonderful skills with all the tech. I mean, if I need help, I ask them like, “How do you do something on Google Docs?” Or, “How do you do something on Drive?” The kids are definitely tech-savvy.
Eric Cross (03:49):
They must love being the teacher in the classroom. They get to—it kind of switches power roles, where they get to teach the teacher something.
Ryan Renee Rudkin (03:56):
Yes. And especially WeVideo, sometimes we’ve had some hiccups, and the kids show everybody, and that’s part of the design class. They’re trying to solve—we’re teaching them how to solve their own problems. So if there’s any kind of issue with anything with the technology, honestly, I usually tell them, “Go ask a friend,” or we kind of shout out, “Hey, who knows how to troubleshoot this?” And the kids are eager to help each other, which is nice.
Eric Cross (04:21):
And they have this authentic experience where they’re actually doing real problem-solving, as opposed to something that we manufactured. Like, those are real things that we have to deal with in life. And that’s exactly like how we solve it, right? We just go ask people! We look it up, and the ahas are genuine too. Throughout!
Ryan Renee Rudkin (04:36):
Yes, especially thinking on the fly. Especially yesterday, I was in the middle of teaching and my laptop froze, and it’s like, “OK, everybodytake a couple minutes, you know, work on this, this, or that while I switch out laptops!” And so I’m modeling, too, how to solve my own problems. And I think it teaches the kids how to do that too.
Eric Cross (04:59):
I’ve always thought it was interesting that when teachers get to teach in real time, how do we handle stress and frustration when it’s really happening? And I think the tech—at times, failure is the real one where you feel this chill or this sweat that kind of comes over you and you’re trying to present or cast or the video won’t play and things like that. I think I’ve done enough times in my years of teaching where now my students know what to do, or they want to come up and help, and we’re good with it. But I remember in the beginning when those things would kind of glitch or go wrong or the wifi goes down, and you’re like, OK, what do we need now?
Ryan Renee Rudkin (05:33):
I think it’s honestly, after the fact, when I think in the moment, I’m not thinking of feeling stressed, but just afterwards, then I’m like, “Oh my gosh, this has just been a wild day.” But yeah, you just have to kind of go with it. And that’s just the beast of middle school. I just added to the list of why we love it.
Eric Cross (05:53):
You said something about interdisciplinary work, and I wanna kind of ask about that. Because it sounds like you’ve had your hand in several different areas of science and grade levels. Working, doing design courses, working with tech. Are there certain lessons that are your favorites to teach? The ones that you really enjoy, or that no matter what, you’re like, “We need to do this; this is such a rich experience for students”?
Ryan Renee Rudkin (06:17):
Yeah. I definitely try to do lessons or activities along the way. I like to do projects at the end of my units. When I taught physics, we did a project and it was mainly an assessment tool called the Wheeling and Dealing. The kids, they would all get a different car. And then they to sell their car. And so they had to pretend to be a car salesman, and they did that with their knowledge of the physics unit. So everything we did on forces and speed and motion. So I like doing culminating projects like that. And you’re kind of tricking them into assessing them.
Eric Cross (06:57):
When I think about your car salesman project, I’m thinking of a bunch of students, but they’re like on Shark Tank, but they’re just littler versions. And they’re doing these sales pitches, but they’re speaking in scientific terms as they’re trying to do it. Do you record these or do they just exist in the classroom?
Ryan Renee Rudkin (07:12):
No…And that was a long time ago, when I taught eighth grade. I wish I had; I wish I had recorded. That was definitely—it was fun, ’cause the kids, they would get their little piece of paper and they—some of ’em didn’t know what car it was. And so they’re like “A Boo… A Boo-gatti? What’s a Boo-gatti?” And then someone from across the room would be like, “Ooh, I want it! Here, I’ll trade you my Ford Focus!” And <laugh> so they would kind of wheel-and-deal which car they would…and then once they got their choice, then they would do the project.
Eric Cross (07:44):
So they’re really embodying this persona of a car salesman. The wheeling and doing back-and-forth and trying to trade a Bugatti for a Ford Focus. <Laugh>
Ryan Renee Rudkin (07:53):
I know. <Laugh> I like to make my class, my learning environment, enjoyable. You know, I gotta be there; they gotta be there. So I know there’s other goals in mind—you know, standards and test scores—but at the end of the day, I wanna come back, and I want them to come back. And I just have that as a priority.
Eric Cross (08:18):
Well, based on the projects that you’re doing and the way that you approach education with students, I can see why middle-school students would want to come back, even if they had the option not to. Just because of the cool things that you’re doing. Now we’re on this—hopefully, fingers crossed—tail end of COVID in the classroom and schools, and I know it’s impacted all of us differently. Has student engagement changed since COVID and if so, how, and what have you done in these last two years to maybe adjust your approach, to continue that engagement and that richness that you provide for your kids?
Ryan Renee Rudkin (08:57):
I definitely—I think for me, I recognize that when the students are in my classroom, I want them to, I dunno, for lack of a better word, just escape the noise at home. And I know we’ve always had students that are going through divorce situations or their dog died, other things, but I think with COVID, it’s definitely been compounded. And just creating a safe place for the kids to want to be and…it’s hard. We’ve had a lot of students that have been out, absent, for various reasons and on quarantine. And they’re struggling with doing work from home, ’cause their parents are stressed and their parents are dealing with their work issues. And so I think just having grace for the kids and just keeping…I don’t know, I guess like I said, I’ve always had student engagement as top of my list.
Eric Cross (10:06):
It sounds like—the things I hear you say really have to do with who these students are as people.
Ryan Renee Rudkin (10:12):
Yeah.
Eric Cross (10:13):
And then as a second, who they are as students. How do relationships fit into your engagement? ‘Cause I’m hearing this connection that you seem to be making with kids as you’re talking about things that are beyond academics: their home life, how they’re impacted.
Ryan Renee Rudkin (10:28):
Yes.
Eric Cross (10:28):
Is there anything that you do to build these relationships, or to connect with your students, to make them feel wanted or feel connected to the classroom or to you?
Ryan Renee Rudkin (10:37):
Yeah, I do. I do a few things to build those connections. And again, this timeframe in their life is so out of their control, their peer relationships, relationships with their parents. And when they’re in my classroom, I want them to feel loved and appreciated. Something I do it’s called Phone Fridays. And in one of the social media groups, someone posted about it, and I’ve been doing it for over a year now, actually. So on Fridays I call parents and give good news. And so I’ll pick maybe one or two students. And it could be academic reasons. It could be behavior, I’ve seen a slight improvement of behavior. Maybe a role model in the classroom. And my goal is to get everybody every trimester. So everybody gets a phone call by the end of the trimester. And it’s funny ’cause sometimes the parents are a little like “Uh-oh”! When they pick up, they see the caller ID, and their school’s calling. ‘Cause Some kids don’t get good calls. So it’s a really—I would say every single parent that I’ve called, I usually get a follow-up email, either to me or my admin, just saying it’s such a cool idea I do this; thank you so much. And yeah, I just call and give good news and just put ’em on the spot. And usually the kids are a little embarrassed, but you can tell, even though they’re kind of—I think they’re faking it, that they’re embarrassed! ‘Cause You know that they got the Phone Friday, and everybody’s like, “Who’s gonna get the phone Friday?!” And so it’s a very big deal in my class.
Eric Cross (12:07):
What a great way to—I mean, it seems like that hits on so many levels. You’re making these positive calls home. You’re praising publicly, which a lot of times can happen where students can get criticized or redirected publicly and then praised privately, which is a lot of times the reverse what we should be doing. But here you are praising them publicly. And then you’re not only building a relationship with yourself, but you’re also connecting them with their parent or whoever is caring for them, because now when they go home, there’s this, “Hey, your teacher called; you’re doing awesome!” So it’s this kind of triangle that’s forming there. I think that’s super-cool and a great thing for teachers to do.
Ryan Renee Rudkin (12:45):
It takes, you know, the last five minutes of my class. I do it every class. And then I have a system. Like I said, I keep track of all the kids. That way, by the end of the trimester I’ve gotten everybody. Sometimes I let the students, whoever I call first, then I let them pick a peer and I tell them, “OK, we have to have a solid reason. Why are we calling?” And a couple times they’ll have a student, like one of my energized ones, they’ll raise their hand. “How About me? How about me?” And I and the kids kind of laugh a little and I said, “Well, how about this? Let’s make a goal. How about next week we’re gonna make a goal and we’re gonna have a reason to call home.” So just working on the kids that need a little push in the right direction. That’s other reasoning to it. But yeah, it’s fun. I love it.
Eric Cross (13:33):
And you have the community. You have this goal setting. We were talking a little earlier about this transition—so you’re becoming this…your school’s going through the IB process, is that right?
Ryan Renee Rudkin (13:44):
Yes.
Eric Cross (13:44):
And we were talking about the ATL skills and one of them is goal-setting management. You already kind of organically do this in your classroom, which is really neat. I know being an IB teacher, a lot of times I find the things that I’ve already been doing and find, “Oh, this is actually an approach to learning!” or “This is something that has a title!” I just thought it was just being helpful! Ah…So the kids are connected. You have this process where you’re calling parents; it’s working; students are involved, so it’s building this community. Now you’re engaging students. Do you have any favorite student engagement tools that you use in your classroom or when you’re teaching that you feel like you get a lot of bang for your buck? There’s so many things out there these days. And so many approaches, tools, web apps. Do you have any favorites that you use?
Ryan Renee Rudkin (14:40):
No. Nothing comes up top of my mind right now. Mostly just projects, like I said. And being excited. I think having my students see me excited about something…and I’m honest when we’re doing something that’s not quite my favorite, then I’m honest about that too. But just having my—like, we just started thermal energy this week and I told my students, I said, “OK guys, I’m gonna weave in some chemistry in there. I’m gonna weave in some particle motion,” and they’re like, “Oh! That’s when you taught eighth grade, huh!” Cause I talk a lot about when I taught eighth grade before. I don’t know, just showing my own enthusiasm, I think, is a good payoff to me. That’s a bang for your buck. Other things…I try to give ’em cool videos and Mark Grober, he’s definitely a favorite of mine I like to show my students. I like to bring in guest speakers from our community. When I taught eighth grade for physics, I always brought in a local CHP officer and they would bring in the radar and lidar guns and the kids would mark off the parking lot and they would calculate their speed. And then they would verify it with the radar gun. Two years ago when I taught math, I brought in a local landscaper company, a father-and-son outfit, and they showed the kids how they would do bids on jobs. And so, relate it to our chapter on volume and area. So just making that connection with real life. Plus it’s just a nice opportunity, too, for the community to come in. With our design class, put on our newscast. And then one of our units in our sixth grade curriculum is weather. And so I brought in a local weatheruh, chief meteorologist. And he actually talked to the students about his job as a meteorologist and then also being on the news and putting on a newscast. So we got him on our green screen and did a little like Mark Finan, you know, little cameo on our newscast for the week for school. So that was kind of cool.
Eric Cross (16:45):
They must have been excited.
Ryan Renee Rudkin (16:47):
Yeah. They’re pretty starstruck by him. So that was pretty fun.
Eric Cross (16:51):
This person was on their local news? So they would know him?
Ryan Renee Rudkin (16:56):
Yeah, he’s on Channel 3 out of Sacramento. Yeah. KCRA Channel 3, Mark Finan.
Eric Cross (17:00):
So all these guest speakers that you have…how do you reach out to these people? And you sound like you get a lot of success. Do you ever get nos? Like if I’m sitting here listening and that inspires me, but you’re getting celebrities and you see a few people…like, how do you reach out to them? And does everybody say yes? How does it go?
Ryan Renee Rudkin (17:21):
Well, usually at my back-to-school night, I always ask the parents if they have a career or hobby that could lend itself to the curriculum. And so sometimes I’ll hear about—students will talk about, like, “My mom’s a doctor.” And so I’ll reach out to parents and just say, “Hey, you know, your kiddo said, you’re a doctor. May I ask what type?” And most of the time the nos that I’ve received are just because of schedule conflicts. You just have to get creative! Look in your community and see what you have. People want to come and talk to kids. I’ve had some presentations that the person is so intelligent and amazing, but they just, weren’t very kid-friendly. I mean, that happens. Butsomeone knows someone. And just ask! I mean, it doesn’t hurt to ask to have ’em come out, come hang out for the day, with my students. Andone time I had a nurse practitioner she was in the cardiac unit. And so she brought in hearts and led a heart dissection with my students. And we did a station set-up. I’ve had elaborate ones like that, or just a mom come in to tell my students about her job as a nutritionist and relate it to our unit on metabolism. And so just did like a little 15-minute Q&A with the kids on nutrition. And I would just say, look at your community and/or post on social media. I always do that. Post in your school’s PTA groups. So the parents know someone, that’s for sure. Or someone’s retired. One time I had—I think he was a grandfather of one of the kids—he was into rocks. And he had a bunch of meteorites <laugh> and brought in his meteorites.
Eric Cross (19:15):
Bring in your rocks!
Ryan Renee Rudkin (19:15):
I know! Right? And he <laugh> just brought in his meteorite collection! I was like, sure, come on in!
Eric Cross (19:23):
That’s one of the things I love about being a middle-school teacher is that my students have such varied interests and I’ll get the Rock Kid every once in a while and he’ll come in and he’ll have all these rocks and crystals. And a lot of times there’s a grandfather that’s responsible for this inherited geologic treasure that they have.
Ryan Renee Rudkin (19:45):
Yeah, something like that—I mean rocks are not my favorites, but I don’t really tell the kids that. I was like, “Sure, yeah, come on in! We can have a whole-day lesson on rocks!”
Eric Cross (19:55):
<Weakly> “This is great!”
Ryan Renee Rudkin (19:58):
Just utilizing your resources. That’s all it’s about.
Eric Cross (20:02):
Well, I think the back-to-school night was really helpful. That’s something that’s super doable. You have a bunch of parents and you just simply ask, “Who do you know? What do you do?” And then just collecting that and then just asking people to come in. I’ve I’ve been reluctant to do it more often than I’ve wanted to, because I haven’t figured out—and maybe you can help me with this—I have three class periods a day plus other class periods that are not necessarily science. And I don’t want to dominate a person’s schedule. Do they tend to be willing to stay all day? Or do you do, one class gets it, and you record it? Like, how do you balance out the speakers with your school schedule?
Ryan Renee Rudkin (20:39):
Mostly they’ll they’ll just come for the whole day. When I taught eighth grade, I had five classes, so that was easy. That was an all-day thing. And then usually I’ll offer to call lunch, have lunch delivered, or snacks during the day. I mean—
Eric Cross (20:53):
Feeding them is key.
Ryan Renee Rudkin (20:54):
Yeah. Just something kind of nice. Donuts in the morning. I mean, you’d be very surprised. Most people that are in the field or retired, like I said, they’re more than willing to come. And even if they have to wait an hour, while you teach another class that doesn’t pertain to it, then they’ll either leave or come back or just hang out in the back and pretend to be a student during that history class that you have.
Eric Cross (21:20):
It’s my own limiting belief where I feel guilty. I don’t think about it. I need to think about it through the perspective that you do, that these people WANT to talk. I just assume everybody’s so busy. But I do know, the times I’ve had speakers come out, at the end of the day, they’re so energized or they’re so happy or they’re so grateful. ‘Cause They’re like, “This is what it’s like to teach every day?” I’m like, “Yeah, this is what it’s like.”
Ryan Renee Rudkin (21:42):
I think too, a lot of parents…usually being being in the stops at elementary. A Lot of parents don’t get the opportunity to come help out in the classroom, because the middle school kids, you know, it’s not very cool or it’s just not needed like in the elementary classes. So a lot of times, like I said, you’d be surprised. A lot of the parents they’re more than happy to come and hang out. And again, some students, they don’t want their mom or dad to be there, but then I talk it up. I’m like, “Everyone’s gonna be so like impressed that your dad’s a doctor,” or “your mom’s a doctor” or —so then I kind of like downplay it. Like, “Oh, whatever, you’re you’re faking it. It’ll be fine. Don’t be embarrassed.” Leading up to their parent coming into the classroom.
Eric Cross (22:36):
Right. Kind of redirect that energy toward something positive. With guest speakers, projects, pacing, all these awesome things that you have going on, how do you find balance as a teacher, as a person? And what encouragement would you give to new or aspiring teachers? We work in a profession that will take as much as you give it. And you fall asleep at night worrying about other people’s kids and we love it. And teachers by personality can just give and give and give and give. But in order for us to last—I’m thinking about those new teachers who are going into it, who are gonna go in and be there before the sun gets up and stay after the sun gets down. How do you maintain balance, taking care of yourself? You’ve been in education for—how long have you been teaching for?
Ryan Renee Rudkin (23:29):
Sixteen. This is my 16th year.
Eric Cross (23:31):
Enough to be that veteran. So how do you find balance? And then, what encouragement would you give to new or aspiring teachers?
Ryan Renee Rudkin (23:39):
I would say each year, pick one or two things to add on. You can’t add on 10 things, even though you’re gonna find 10 things that are awesome. But just make a little list, put ’em in a file, and every year, just get good at what you do and then just add on one or two things. And reflect on what’s not going well that you can get rid of to make room to add something else. Try to be patient with yourself. And don’t reinvent the wheel. There’s so many things out there that you can borrow and make it your own. Again, I think that’s a time-saver, just leaning on your colleagues. And take lots of notes, because then when you do it again next year, you can refresh yourself and, “Oh yeah, this lesson, wasn’t the best…” What can you add in to make it a little bit better? And yeah, I would say just take on one or two things each year. And then by the time you get to, you know, being a veteran, you can do all these awesome things and it’ll feel natural ’cause you’ve been practicing and just adding in one thing at a time. I coached Science Olympiad a bunch of years ago, and Science Olympiad is so rewarding. It’s just so amazing.
Eric Cross (24:59):
What is Science Olympiad, for the people who’ve never heard of it?
Ryan Renee Rudkin (25:03):
Oh, Science Olympiad is so awesome. Google it. I think it’s just ScienceOlympiad.org. It’s 23 different events across all disciplines of science, different topics. And then you have a team of 15 students. And so your 15 students have to cover the 23 events. So for example, if the student’s on the anatomy team, usually there’s a team of two kids they’re gonna study and learn. They provide all the rules and the guidelines. So the students learn and study whatever the parameters are for that year. And then they take a test. And then they compete against other schools. And there’s build events, the engineering events, they can build things like trebuchets matchbox cars or mousetrap cars. Oh gosh, there’s all kinds of things. There’s like a Rube Goldberg device. It changes every year. And it’s so rewarding to see the kids; they pick their area of science that they love. And sometimes you have to put them on an event that they don’t know, and then they end up loving it. It’s so rewarding as a teacher to see these kids that are just on fire and you know that one day they’re gonna go off and do amazing things. They just commit. They commit to their event. And then they blow it outta the water and they win medals and just the recognition…it’s super, it’s just an amazing program.
Eric Cross (26:42):
One of the competitions that’s really low-tech that I’ve taken into my classroom is Write It, Do It. Have you done that one before?
Ryan Renee Rudkin (26:50):
Oh, yes. Yeah. That’s one. Yep.
Eric Cross (26:52):
It’s such a low-tech, simple one to do, but it teaches such great skills. And for those people who haven’t heard of the Write It, Do It project, you create kinda some abstract art out of random crafts. That’s very difficult to describe. You have pipe cleaners and foam and balls and you know, all these different things. And you make it. And then one person on the team is the writer, and they look at it and they write the procedures, and then their teammate, who’s in a different room and doesn’t get to see it, gets all the materials to build it and the procedures, and they have to rebuild it as closely as possible to the actual original. Even though they don’t get to see the original. So they have to rely on their partner’s ability to write procedures step-by-step. And it was fun to watch my students become teammates in that. And they learned how to communicate in a really fun competition. So I expanded it to do it with all of my students as an activity, just to teach them how write descriptively, to write procedurally, to be technical writers. And it’s, it’s fun! It’s fun to see what they build based on what the students say. <Laugh> And it’s also fun to watch them interact with each other, which for seventh graders, usually it’s conflict. <Laugh> But, like, playful conflict. <Laugh> It’s pretty funny to see what they build.
Ryan Renee Rudkin (28:11):
They’re like, “Man, what are you talking about? That doesn’t mean this; it means this!”
Eric Cross (28:16):
<Laugh> I know part of me feels guilty, but not enough to stop the project. ‘Cause I know for some of ’em, it’s gonna be a really trial by fire being able to practice their skills with writing procedures.
Ryan Renee Rudkin (28:27):
But they’re learning among themselves how to provide more details and to be more thorough with their writing and and their thoughts, put their thoughts onto paper. So yeah, that’s a funny event. Definitely.
Eric Cross (28:41):
Earlier you had mentioned something about connecting your kids with kids and students outside of your classroom. What is it that you do with that? Because I thought that was a really cool project. Can you speak to that a little bit?
Ryan Renee Rudkin (28:57):
Yes, I’ve done—they haven’t had it in a few years, but there’s something called the Pringles Challenge. And if you Google that, I’m sure it’s on the Internet still. So you sign your class up, or your classes, and you get partnered with another school somewhere in the U.S., someplace else. And you decide individually teams, whatever they build. And they make a package to ship a single Pringle chip through the mail. And then you actually mail a Pringle chip through the mail. And then your partner team or partner school, they send their chips to you and then you open everything and then you can take pictures and video. And then there was a whole scoring process where you would score when you receive the chips. And then you input all the data on the website so you can see like how your—and most schools would trade pictures, so that the kids found out how their chip survived. March Mammal Madness is so much fun. Again, Google that.
Eric Cross (30:01):
Did you say March Mammal Madness?
Ryan Renee Rudkin (30:02):
Yes.
Eric Cross (30:03):
Like March Madness, with mammals?
Ryan Renee Rudkin (30:05):
Yes.
Eric Cross (30:05):
- What is this?
Ryan Renee Rudkin (30:06):
It starts up in March. And you can sign your students up. And that one—it’s not too interactive with other schools, but this is opportunity to get the kids interacting within your site or within your district. Or if you have teacher friends at other schools. There’s like 60…I think it’s 64 animals? And they have this massive bracket that they post. And then you can have the students, I did it—it would be very time-consuming to have the kids individually research each animal. So I just gave one animal per student and so as a class we researched all the animals and then, I think it’s every three days or so, they have these bouts. And it’s all posted on YouTube. Google it. It’s kind of fun.
Eric Cross (30:56):
I’ve already got the website up, ready to go! Folks, everybody who needs to Google this: <articulates carefully> March Mammal Madness. And is it Arizona State University? Is that the main site, ASU?
Ryan Renee Rudkin (31:04):
Yes.
Eric Cross (31:04):
So people, listen to this. Check it out. March Mammal Madness. Look, I’m doing this! I’m already,—you’ve already sold me on this.
Ryan Renee Rudkin (31:14):
It is so much fun, oh my gosh. And then, then the kids—each round, they pick their pick, just like basketball. They do their picks and then you wait for the video. And they do it live on—I think it’s live on Instagram, or the next day on YouTube. And then the kids get all excited. And then usually the kids, whatever animal they got as their research animal, they’re rooting for that one to win, the whole thing.
Eric Cross (31:42):
But we still have time; we still have time to—
Ryan Renee Rudkin (31:45):
You can jump in anytime. Even if it’s already started, you can jump into it. It usually lasts—I believe it’s a two-week from beginning to end. When they do the first round, the wild card, and then all the way to the winner, I believe it’s a two-week process. Oh, maybe three, actually.
Eric Cross (31:59):
I’m already seeing this lead-up to the video being watched in class to see…I’m already thinking about like, “How do I prevent my students from finding the video?” Or like, “When does it go live so that I could be the one to show them so they didn’t go find it early?”
Ryan Renee Rudkin (32:13):
It takes time out of the class, but I believe it’s one of those things where you have to just…it takes 10 minutes out of the class, but it’s important. So when they each round and then the next day, they release the YouTube video. Last year, when it got down to the final round, we were on spring break. And so I told my students, “You guys, let’s do some optional Zooms. And so I had a bunch of kids log on and we all watched the videos together. So that was kind of fun. And then this year, the other thing, the first time I’ve ever done this and it’s going really well is—on social media, I was talking with one of the teachers from Ohio who teaches science and she and I decided we’re gonna do penpals for our students this year. Paper-And-Pen penpals. So that’s been a lot of fun. We just partnered up all the students, her students and my students, and once a month we send and receive the letters to each other. So that’s been a really cool experience.
Eric Cross (33:14):
If you keep doing that, and you need more teachers to be involved, can my students be penpals with your students?
Ryan Renee Rudkin (33:20):
Yeah!
Eric Cross (33:20):
If you open it up to more people? I think that, to get a letter, old-school? Letter in the mail? It would be so exciting.
Ryan Renee Rudkin (33:28):
It is. We mail them, the teacher and I, we just put them all together in one package. But yeah, it’s an actual handwritten letter.
Eric Cross (33:37):
The only letters I feel like I get in the mail now are bills.
Ryan Renee Rudkin (33:42):
Right? Exactly.
Eric Cross (33:42):
But I feel like the digital version of that is if someone calls me, it’s probably bad news. I don’t know if I’m the only one that’s like that, but I’m like, “Who’s calling me? Why aren’t you texting me? What’s going on? Text me first, then call! I need to know who’s going on, and if you’re unknown, you’re going to voicemail.
Ryan Renee Rudkin (34:00):
Exactly. The penpals has been a lot of fun.
Eric Cross (34:03):
You’ve been in education for a while. You’re on the other side of what it’s like to be a student in the classroom. Which can be surreal in itself, when we think about our own experiences as being a student. Is there a teacher or a learning experience that’s had an impact on you while you were a student in school that really stands out to you? And you can interpret the question however you want. But is there someone that’s memorable or an experience that’s memorable that you still carry with you today?
Ryan Renee Rudkin (34:32):
Definitely. My favorite teacher, and we actually still keep in contact on social media is Mrs. Sheldon. She was my fifth and sixth grade teacher. I had the pleasure when I was in elementary school, I was in an all-day contained GATE class—Gifted and Talented Education class. I vividly remember doing so many amazing projects. We built this big, giant—she brought in a big ol’, like, TV box. It was big, big, big. And you could stick like three kids inside there, standing up shoulder-to-shoulder. And we built this big dragon. The head, and we had the whole rest of the class in a big sheet behind us, and we would do a little parade around the school. And she had that thing for years after. They had to repair it every year, and they would do the little parade around school. She did a lot of traveling and when we would go on vacation and then come back, that was always the big deal: “Where did Mrs Sheldon go?” And she had sand from Egypt and pictures from the rainforest. And later when I became a teacher and then I looked her up and we reconnected I did ask her, “Did you go to those places? Or did you, like, lie about it? <Laugh> To get us engaged?
Eric Cross (35:52):
You went for the real questions!
Ryan Renee Rudkin (35:54):
I did. And she laughed and thought that was funny. And she did travel for real. But yeah, she’s an amazing woman. We still keep in contact. And I remember, you know, little things…like we would be out there doing our PE time and she’d have her long skirt, you know, dress on, with her tennies, and she’s out there playing kickball with us. Just a very kindhearted, smart, amazing woman. I’m very fortunate and I’m grateful that we are able to keep in contact. Love social media for that reason. So.
Eric Cross (36:33):
Yeah. And that’s Miss Sheldon?
Ryan Renee Rudkin (36:35):
Mrs. Sheldon. Marlene Sheldon. Yeah.
Eric Cross (36:37):
Shout-Out to Marlene Sheldon influencing the next generation of teachers, with engagement with your world travels and all those different things.
Eric Cross (37:04):
Ryan, thank you so much for one, serving our students. And in the classroom, our middle-school students who need us. I think that middle school especially, elementary school, those years are when students are really starting to decide, “What am I good at?” And the experiences that we create for our students really shape what they believe they can do. These really cool, engaging experiences, these projects that you’re giving them, whether they’re doing these car sales, Shark Tanks, or they’re doing penpals, or you have guest speakers, or they’re designing planets. These are things that students don’t forget. And then when they move on to higher grades, they remember more than anything, I think, how they felt about something. And it sounds like you’re crafting these awesome experiences. And so I just wanna thank you for your time. I know as a teacher it’s very short. And I thank you for being on the podcast with us.
Ryan Renee Rudkin (38:04):
Thank you. This has been a great experience. I just—I really enjoy my students. And I feel very, very grateful and very blessed for finding where I belong.
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Meet the guest
Ryan Rudkin is a middle school science educator near Sacremento, California. Although she originally thought she would teach elementary students, Ryan connected with middle school and never looked back. Now in her 16th year in the classroom, Ryan also supports teachers in her district with professional development. Ryan’s favorite part of teaching science is seeing students grapple with concepts and explore phenomena.
About Science Connections: The podcast
Welcome to Science Connections: The Podcast! Science is changing before our eyes, now more than ever. So…how do we help kids figure that out? We will bring on educators, scientists, and more to discuss the importance of high-quality science instruction. In this episode, hear from our host Eric Cross about his work engaging students as a K-8 science teacher.
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S1-05: How does coding fit in the science classroom? A conversation with Aryanna Trejo of Code.org
In this episode, Eric sits down with Aryanna Trejo, a professional learning specialist of Code.org. Aryanna shares her journey from working as an elementary teacher in New York City and Los Angeles to teaching other educators at Code.org. Eric and Aryanna chat about computer literacy within the science classroom, problem-solving skills, and ways to model productive struggle for students. Aryanna also shares ways to teach coding and computer literacy in schools, no matter the classroom’s technology level. Explore more from Science Connections by visiting our main page.
Aryanna Trejo (00:00):
I would hear teachers saying things like, “Well, I just can’t do coding; this is too hard for me; the time has passed.” And I would ask them, “Would you say that to your student about math or English?” And they would always sheepishly go, “No.” And I’d say, “Well, be as kind to yourself as you would be to your student.”
Eric Cross (00:19):
Welcome to Science Connections. I’m your host, Eric Cross. My guest today is Aryanna Trejo. Aryanna is a member of the professional learning team at Code.org. Before joining Code.org, Aryanna led computer science professional development for elementary school teachers, and served as an instructional coach for new educators. She also taught fourth and fifth grade in both New York City and in Los Angeles. In this episode, we discuss Aryanna’s journey to Code.org, where she helps educators connect coding to real life, how to use a rubber duck to solve problems, and how coding and computer science principles can be taught to students in areas without access to the internet…or even a computer. I hope you enjoy my conversation with Aryanna Trejo. So I was born and raised here, and I saw that you went to UC San Diego.
Aryanna Trejo (01:11):
I did, I did. I actually just put a deposit down on an apartment in University Heights, ’cause I’m moving back.
Eric Cross (01:16):
You’re coming back?
Aryanna Trejo (01:17):
I’m coming back. Yeah.
Eric Cross (01:19):
So if you need a classroom to visit….
Aryanna Trejo (01:21):
I would love to do more classroom observations!
Eric Cross (01:24):
Are we doing this? Let’s do—we’re making this happen.
Aryanna Trejo (01:26):
We are. Yeah. So I’ll be there. I’m moving there in April. I actually grew up in Orange County too, so I’m like a very diehard SoCal person.
Eric Cross (01:35):
So I feel like I know the answer to, hopefully—Tupac or Biggie? ‘Cause you’re on the East Coast, and you’re on the West Coast.
Aryanna Trejo (01:40):
Yeah. I like Tupac, but I have more Biggie songs committed to memory. Which is not a lot. I have “Juicy” and “Hypnotized” memorized.
Eric Cross (01:53):
All right. So you’re just memorizing, and you have the Biggie songs memorized, but not the Tupac ones.
Aryanna Trejo (01:58):
No, but I do love Tupac songs. You know, it’s like, Biggie has the flow, but Tupac has the lyrics. Nobody’s—they both have something really amazing about them.
Eric Cross (02:06):
You know, I can respect that you broke it down into both of their strengths.
Aryanna Trejo (02:11):
Thanks for buttering me up before this interview. And not….
Eric Cross (02:15):
<laugh> Oh, we already started.
Aryanna Trejo (02:16):
Huh? We already started?
Eric Cross (02:17):
We’re already started. Yeah. We’re already into this.
Aryanna Trejo (02:19):
We’re into it.
Eric Cross (02:21):
You were in the classroom, fourth and fifth grade, and you were doing TFA.
Aryanna Trejo (02:26):
I did. I did Teach For America. I was 2012, New York City Corps. Right after graduation. ‘Cause I graduated UC San Diego in 2012. So graduation was on June 17th, and I touched down at JFK on June 19th.
Eric Cross (02:40):
Even though I wasn’t in TFA, I know a lot of the fellows that are in it. And there’s just some phenomenal teachers in there. How long were you doing elementary school when you were teaching?
Aryanna Trejo (02:49):
Yeah, I taught for—well, I did, three years of teaching fourth grade. Then there happened to be an instructional coach opening in my fourth year. I took that, did some instructional coaching within the same network, and then I moved back to LA and I taught fifth grade for a year.
Eric Cross (03:11):
- And what was it like now? Did you go to Code.org right after the classroom?
Aryanna Trejo (03:17):
No, I didn’t. No. I transitioned after teaching fifth grade for a year in downtown Los Angeles, in the Pico-Union neighborhood. I ended up getting this email out of the blue from someone who had actually found me through the Teach for America job site. ‘Cause I was hitting the pavement; I was really looking to transition out of the classroom. And she invited me to interview with this company called 9 Dots. And they taught computer science to kids K–6 throughout Los Angeles and Compton. And I was like, “Sure, no problem. Let’s do it.” So I interviewed, I got the job, and yeah, that’s how I transitioned to 9 Dots. And then after almost four years there, I transitioned to Code.org, with the same person. Actually, she moved over to Code.org first, and then she helped me get this job.
Eric Cross (04:07):
Oh, that’s happened a lot—like, that relationship kinda carries over.
Aryanna Trejo (04:11):
Yeah. We’re meant to be coworkers.
Eric Cross (04:13):
Yeah. Are you still? Is she still there? Are you both still together?
Aryanna Trejo (04:17):
Yeah, we’re on the same team and it’s nice. I saw her last night for Happy Hour, with another coworker who’s in LA. So we’re tight. And she’s a wonderful, wonderful mentor to me.
Eric Cross (04:28):
That’s great. Did you have computer-science background, when you were doing elementary school teaching? Did you have—
Aryanna Trejo (04:34):
No. <laugh> Not at all. When I was teaching in New York City, I had like four desktop computers in my classroom, and we rarely used them. Which was such a shame. And then when I moved to Los Angeles and taught fifth grade there, we were a one-to-one school, and the joys of that are just amazing. It was just really wonderful to, you know, get the students used to typing on the computer, using different software to submit their assignments. Getting creative—as creative as you can get—with Google Slides. You know, to show off what they know. And stuff like that. That’s all I had, though. And you know, when I transitioned to 9 Dots I was like, “Sure, why not? Let’s give a shot.” And I learned a lot. It was really interesting, yeah.
Eric Cross (05:26):
And so now at Code.org you are…well, so my journey with Code.org, I’ve been in the classroom for eight years. Still in the classroom as of…an hour ago, I was there. <Laugh> And I use Code.org, and I feel like I’ve checked it periodically, and I feel like it’s evolved over the gaps. And I’ve seen it. It’s become more robust in the things that they offer, over the years I’ve been an educator. Just to kind of…could you give a thumbnail sketch? Like, what is Code.org? Who’s it for? Who’s the target audience? What resources are there?
Aryanna Trejo (06:00):
Yeah. So it’s for everyone. It is a nonprofit that provides curriculum and training and a platform for teachers and students. We provide curriculum for K through 12. It’s completely free. And it comes with lesson plans, slideshows, all that. We focus specifically on underrepresented groups. So we have targeted measures for Black students, for Native American students, for students who identify as female. That’s a huge part of our mission. But we’re really working to expand access to computer science to as many students as we can.
Eric Cross (06:41):
One of the things I’m hearing in your story is you were teaching in Compton; you were in Bronx, New York. One of the reasons why I got into the classroom is because of educators, and the impact they made on me in exposing me to science and technologies I’d never had access to. And that intentionality, that you’re going about it…are there…not just the code, but how you bring that across to different groups…are there strategies, or are there ways to connect this idea of coding to diverse groups and diverse audiences? Or is it kind of, the curriculum applies for everyone? ‘Cause in science, when I’m teaching, I’m always trying to make what I’m doing relevant to the backgrounds of my students.
Aryanna Trejo (07:28):
Sure.
Eric Cross (07:28):
So I’m teaching biology, and I’m trying to make this kind of connection. Sometimes it’s more organic; sometimes it feels kind of forced. Because it’s just not always a nice fit. But it sounds like Code.org is really about inclusion. And in the numbers that I’ve seen for representation, in especially computer science software engineers, the groups that you’re focusing on are not necessarily represented in the professional workforce. At least disproportionately.
Aryanna Trejo (07:54):
Yeah, absolutely. Yeah, that’s correct.
Eric Cross (07:57):
And so how do you go about being intentional about reaching groups that we don’t see in, you know, the Silicon Valley software engineers? How do you start that? Like, at a young age, do you look for specific schools in specific areas to say, “We are going to bring this to the school. We’re going out to these populations of the cities”? Because we’re just not seeing…you know, on the map, we’re not seeing anybody really doing anything with coding here. Or we’re not seeing the numbers come out of these areas, out of these cities, of students who are going into STEM or going into computer science fields.
Aryanna Trejo (08:41):
Yeah. I don’t necessarily work on the recruitment side of it, is the issue, in my position. But I do work on the professional learning, that is brought out to teachers. And we have a huge focus on equity throughout the workshops that we create from K–12. It’s something we’re really passionate about. We definitely aim to prepare teachers to teach computer science. That’s a huge part of it. Knowing the content, but also thinking through, “What does recruitment look like at your school to make sure that the demographics of your classroom match the demographics of your entire school?” Also, thinking through, “How can we make sure that female students feel included in your classroom? How can we make sure that we are, giving students creativity to think about, or we are setting students up to be creative and think about the problems that are in their community, and how they can use computer science to solve them, or at least work towards them?”
Eric Cross (09:39):
So solving real-world problems and that inclusion aspect…are there things like…you were saying “female or students who identify as female”…are there things that teachers can do to ensure that they’re being more inclusive? Or to recruit, or encourage more female students to take part? One of the things I was thinking of, that I’ve seen, is I’ve seen coding kind of camps.
Aryanna Trejo (10:06):
Sure.
Eric Cross (10:08):
That were specifically for a female audience. And that seemed to help with recruitment. Is that something that you see on your side?
Aryanna Trejo (10:16):
That’s not something that we set up, no. But the curriculum that I work with is CS Principles. And it’s offered as an Advanced Placement course, as well as an AP class. So that’s a curriculum that’s designed for students who are in grades 10 through 12. And so at that point, we can really talk to teachers and ask them what the recruitment strategy is. But in terms of strategies that teachers can use to recruit those students…I mean, I’ve heard over and over from lots of different teachers who identify as female that they didn’t think that computer science was for them, until they saw a role model in that position. And so just being a role model for those students is really wonderful.
Eric Cross (11:00):
And I see it too, with—like, we do “Draw a Scientist” activity, which is like a popular science thing—
Aryanna Trejo (11:05):
Sure, yeah, I’m familiar.
Eric Cross (11:05):
But it’s the same thing, right? Like, it fleshes out. My students don’t draw themselves as scientists. They draw what they perceive, based on what television says. I imagine with computer science, it’s probably really similar, when you think about “What’s a software engineer look like?” Do students tend to draw themselves? Or is it even a mystery? Because I don’t even know what a software engineer looks like.
Aryanna Trejo (11:28):
Yeah, absolutely. Well, one of the things we love to do with our professional learning workshops is talk about understanding yourself, your identities, how they show up in the classroom as biases. And, you know, things like stereotype threat. We see that as really important to understand, and think through, and consider, before you step into the classroom. So that you’re not, you know, coddling certain groups of students because you don’t believe that they are able to be successful in computer science. Holding all the students to the same expectations and believing that they can succeed. And computer science, I think a lot of the times people have this conception of it being this utopian, bias-less, technocratic field. When in reality, everything has bias. And people talk about algorithmic bias and facial recognition, but also the people who created computers and computer languages have their own bias that comes through. And I think it’s really important to show students that. So that they can, one, know what they’re working with, and two, make sure that they can create products that reduce that bias.
Eric Cross (12:50):
It’s like…it’s not objective, just because we’re creating software. Like, once it gets to a point of being so sophisticated…I think, like, AI software, right? With facial recognition? And we’re seeing more and more articles come out about, you know, predicting trends based on historical data.
Aryanna Trejo (13:12):
Sure.
Eric Cross (13:13):
But then, the trends and things that they’re seeing tend to target things that have happened in the past. But it also doesn’t take into consideration a lot of other factors that can lead to certain groups or populations being identified. And I’ve seen some articles lately about how your code is really just representation of what you put into it. And like you just said, your bias—if you have that, conscious or unconscious—you’re gonna put that into your code. And the input is gonna be an impact, is gonna impact the output.
Aryanna Trejo (13:44):
Yeah, absolutely. Or even just—and I’m ashamed to say this, ’cause this is an idea that came to me just recently, through an article that I read—but computers themselves have bias. The hardware assumes that you have vision, that you can see the screen, that you are able-bodied, that you can use your hands to work the keyboard, the mouse, et cetera, and that you don’t have to use assistive technology. You know, there are small things like that, where we think that technology, like I said, is this utopian, futuristic science…but there are biases throughout.
Eric Cross (14:19):
You’re absolutely right. I’ve never even—I’ve never even considered that. Even though I do use assistive tech, and figure it out, I’ve never thought from the ground up, the process is built for an able-bodied, sighted, hearing person.
Aryanna Trejo (14:31):
Exactly.
Eric Cross (14:32):
To be able to engage with the hardware. And then these other things, these tertiary things that we kind of add on, so that you can do this, but it’s not designed from the ground up for people who are, you know, different audiences, physically. So I’m glad you brought that up, though. Now I’ve seen—and I haven’t done this—but I know Hour of Code is a big thing. And this is something that’s ongoing. Can you talk a little bit about what Hour of Code is? I know it’s, it’s a big thing for the classroom teachers.
Aryanna Trejo (15:08):
Yeah. So Hour of Code is really exciting, and it’s just blossomed from something small to something tremendous. This year is gonna be the 10th Hour of Code. So what it is, is it happens during CS Education Week in December, during Grace Hopper’s—or to honor Grace Hopper’s birthday. She was a computer scientist and Navy Admiral. And basically the aim of it is to get as many students on the computer doing an hour of code, and demystify what coding is. You know, to do seed-planting. To show teachers that this is something that you can facilitate for your students. And also to show students like, “Hey, computer science is something you can absolutely do. Not just for an hour, but more if you want.” So, yeah. Now it’s worldwide, and it’s really exciting.
Eric Cross (15:58):
That’s awesome. And I think about teachers and I still hear the apologetic—when I’m helping teachers in the classroom with education technology—the self-deprecating “I’m a dinosaur; I’m not good with tech,” which is never true. Like, they’re better than they even realize. And I feel like sometimes there’s still a stigma, too. It’s like <laugh> The Simpsons’ Comic Book Store Guy. The condescending tech support person—
Aryanna Trejo (16:27):
Sure.
Eric Cross (16:28):
—who has that tone. And so I feel like some people have been so negatively impacted by that person. So I know when I’m helping people, I actually try to go full-spectrum the other side. But I’m thinking about teachers’ barrier to entry. Sometimes code is like, “Whoa.” And I don’t teach computer science. Do you see those barriers to entry, or at least the perception of them? And then, what’s the reality for like someone listening, and going, “I’m a fourth grade teacher,” or “I’m a humanities teacher in ninth grade.” What’s the perception that you see, versus reality, with the teachers that you train? Is it much more accessible than we think? Or is there a level of sophistication that you have to have coming into it?
Aryanna Trejo (17:10):
No, not at all. I know computer science, and that says a lot! <Laugh> You know, I know my own corner of computer science. And you know, that’s me being self-deprecating, too. But I think learning computer science has helped me in so many different ways that I wasn’t expecting. I recently took the GRE in hopes of, you know, getting back into grad school. And I think just the way that computer science teaches you to search for bugs in your code, or errors, and kind of tirelessly look at a problem from multiple different angles, I was able to carry that into the math that I was doing. And I noticed just a huge difference in the way that I approached it, and the way that I was open to it. But you asked a great question, in regards to the barriers to technology. In my position at 9 Dots, I was working directly with teachers to lead professional development with them. Sometimes it would be a full day; sometimes it would be an hour after school. And the one thing that I always had in my back pocket that was really useful is that I would hear teachers saying things like, “Well, I just can’t do coding; this is too hard for me; the time has passed.” And I would ask them, “Would you say that to your student about math or English?” And they would always sheepishly go, “No.” And I’d say, “Well, be as kind to yourself as you would be to your student.” You know, it takes some patience and nobody’s gonna get it perfect 100 percent of the time. Have I banged my head against the wall trying to solve one tiny little syntax error in my code? Absolutely! But it feels absolutely phenomenal to fix that. And I was an English major in undergrad, and I had never done computer science before. So it’s something that becomes really satisfying.
Eric Cross (19:07):
Yeah, I imagine. I had someone—a trainer or a presenter—one time bring up the fact that our students rarely get to see us learn in real time.
Aryanna Trejo (19:19):
Yeah.
Eric Cross (19:19):
So we don’t get to ever really model failure. I mean, unless we’re in a classroom situation <laughs> in our failures, with classroom management. Then they see it, they see it! But they don’t get to see us model learning failure. And I don’t mean like failure—and yes, I know, “first attempt is learning,” and “no such thing as failure”—that’s not what I’m talking about. But just when we’re not successful with our code, and then we experience real-time frustration.
Aryanna Trejo (19:42):
Yep.
Eric Cross (19:42):
And they said that is actually a great learning experience for your students to watch you go through productive struggle. And that was really liberating for me. Because now I’m in the classroom, and I’m trying to go through it with my students, and the beautiful thing was, they started helping me. We were all trying to solve the problem. And then we had this authentic problem-solving experience. I think it was like a Scratch program, where we were trying to solve, trying to embed it somewhere, or something. And then, in the background of the class: “Mr. Cross! I got it! I figured it out!” And it was this really neat bonding experience. And I felt that—your ears get red, and you get hot, ’cause you’re not—
Aryanna Trejo (20:19):
Oh yeah.
Eric Cross (20:20):
You don’t know it! And you’re in front of 36 kids! And I said, “OK, I need to tell them how I feel.”
Aryanna Trejo (20:25):
Yeah.
Eric Cross (20:26):
So I said, “Now I feel really frustrated.” Like, “I want to go through this, and here’s my thoughts.” ‘Cause I knew that it would be helpful if they saw and would hear my thoughts. So I just did a quick think-aloud and I said, “In my head, <laugh> I want to just quit,” I said, “But I realize that this is the part where my learning’s happening. So I just want you all to hear what’s going on in my brain.” And now I feel like when I’m doing coding with my students, and it’s just basic coding, I feel much more comfortable, like, not knowing. But I needed someone to release me from that “I have to be the expert in everything” to do it.
Aryanna Trejo (21:06):
And teachers are used to being the experts. Right? And they should be. And coding is just such a different landscape. But I think once you kind of give over to the power of tinkering, I think it’s really gratifying. I love being able to…you can revise a sentence, and then read your paragraph back to yourself in English, and say, “OK, I get it.” But there’s something so gratifying about changing a line of code or a block and then being able to hit play and watch your program come to life, and say, “Hmm, that’s not quite what I wanted. Let’s try something different.”
Eric Cross (21:39):
I love your connection to tinkering. ‘Cause—I had never thought about it—’cause I love tinkering with my hands. But I always think about physical things. But coding is exactly that. It’s tinkering.
Aryanna Trejo (21:47):
It’s exactly that.
Eric Cross (21:47):
That’s exactly what it is.
Aryanna Trejo (21:49):
And a lot of it is, for me, especially when I’m trying something new, it’s guess-and-check. It’s like, “OK, that didn’t work. What if I add a semicolon here? Will it finally work? Or what if I add a ‘for’ loop? Will this get me what I want?” And it’s wonderful because you have that with students as well. Like, you have that record of their thinking, and you can ask them to go step-by-step and tell you, you know, “First, I added this, because I wanted the program to do this,” and so on and so forth. And so you have that record, but you can always get rid of it. Students often wanna get completely get rid of it. That’s something that I’ve noticed a lot as I’ve taught computer science. But, once you can get them to target the specific parts of the program, tinker with that, and continue, that’s a really wonderful learning space. There was also something you said about modeling failure. I love the fact that in computer science you can model failure for your students. You said to your students, “I’m getting frustrated.” I love that, because I never got that in math. Nobody ever showed me what it was like to be frustrated with graphing a parabola. Right? Like, my math teachers were always like, “Doot, doot, doot, here you go, you’re done!” <Laugh> And I would get so frustrated, because it didn’t come that easily to me. And I think there’s two parts to that. So there’s modeling the learning and the thinking and the productive struggle, but also there’s the identity of being a computer scientist and modeling what that looks like. So for me, when I get really frustrated with a program, I walk away. I take five minutes. I take a deep breath. I say, “I’m not gonna think about it in these five minutes.” And I come back to it. And I think once you start teaching computer science, you can facilitate that for students. And there’s so many different strategies that they can pick up. They can pick up rubber ducking, which is where they pick up a rubber duck or a similar object, and they talk to it as if they were a partner and talk through their code. And oftentimes, as you’re rubber ducking, you’re gonna find that error, because you’re explaining it to someone who’s a stand-in for a novice. And rubber ducking is a well-known strategy for computer scientists who make it their career. You know, there’s pair programming. Some students love pair programming; some students hate it. But the students start to build this identity about how they problem-solve. And how they approach failure. And I just love that.
Eric Cross (24:31):
I’m writing this down. Because the rubber-ducking strategy, I love. I just imagine my seventh graders, a bunch of 13-year-olds with, like, rubber on the desk. And not necessarily in coding, but I was thinking in my science class. And they’re working through a challenge, and they’re all looking at this duck, and they’re talking to it. But I just love the the idea of externalizing your thought process and talking through it yourself so that you can hopefully arrive at a conclusion. But it’s such a great practice, and this is something that’s been around for a long time, apparently. So.
Aryanna Trejo (24:59):
Yeah. Yeah. It’s a real thing. And you know, you can go low-fi. It doesn’t have to be a rubber duck. You can have students talk to their pencils or their imaginary friends. That’s not the issue; the issue is, you know, talking to somebody.
Eric Cross (25:10):
I know you support teachers. But I just wanted to…I was just curious about your typical day, what that’s like. And then what you do, how you support ’em.
Aryanna Trejo (25:15):
So, at my previous job at 9 Dots, I was in there with the teachers in the classrooms. I was coaching our internal staff who went out to co-teach with teachers. And I loved that. And I had such a great impact on a local scale. But now at Code.org, I have a much broader impact. But I don’t get to interface with—that’s such a tech-y word!—I don’t get to interact with—
Eric Cross (25:42):
You work at Code.org! You get to—
Aryanna Trejo (25:42):
I know! But I’m a teacher at heart, forever, right? That’s my identity that I forged when I was 22 years old. And a typical day looks like opening up my computer, taking a look at my calendar. I often have meetings to talk about, different things that we’re doing to support our facilitators who go out to our teachers and lead their workshops for them. I recently worked on a product that was designed for CS principles, teachers, to onboard to the course if they weren’t able to get into an in-person workshop. And it’s completely self-paced, so it gives teachers an on-ramp into the course. And now I’m working on some in-person workshop agendas. So I feel really wonderful that my work is going out to thousands of teachers. But at the same time, I really, really miss talking to teachers. Because that’s something that energizes me so much.
Eric Cross (26:46):
When should students start learning computer science? I feel like we see it in this kind of narrow lane. Like, this is computer science if you make an app. Can it be more than that? As far as like the benefit of computer science? And—I guess two-part question—when should students, one, start being exposed to it? And then two, what are some of the benefits beyond just, “I wanna just make an app”?
Aryanna Trejo (27:08):
I taught coding to kindergartners. It can start as early as you as you want it to. And it doesn’t necessarily need to be on the computer. A lot of students that I worked with didn’t have computers at home, were interacting with computers for the first time. And that’s a huge barrier, of course, to a lot of teachers. But there are so many unplugged lessons that you can do to start to start to have students think about algorithms, which is just a series of steps to complete to solve a problem. As long as a student can use a computer, I think they can do computer science. There are products out there like codeSpark, where students—and Code.org has these products too—where students are moving an avatar around a board, kind of like a quadrant to…you know, they feed the directions to a computer and then the computer enacts it for them. And with that, they can learn algorithms. You know, that is computer science. And a lot of people don’t see it that way, but it really is. And it starts to set students up for more complex thinking as they move on.
Eric Cross (28:13):
One of the biggest underserved communities, geographically, are students in rural areas.
Aryanna Trejo (28:20):
Yep.
Eric Cross (28:21):
They can be reservations; they can be places just not an urban area. Is there a way to serve our communities of students and bring these skills in an unplugged way?
Aryanna Trejo (28:32):
Yeah. Yeah. If you typed in “unplugged computer science lessons” to Google, you’ll have a ton of hits. And there are so many students out there—not just in rural areas. But there’s incarcerated students. It hurts my heart to even say those words, but in urban areas too. Like in my classroom, where I only had four desktop computers. Access is a real struggle. And there’s things, like I said, instead of moving an avatar around a grid on the computer, I used to have an actual mat that I would take out to my kindergarten classrooms, lay it out, and it would have a grid on it. And we’d have one of the students act as the avatar and the rest of the students would give them directions to get to a different point on the grid. And there, you’re building an algorithm or just a series of steps. Like I said, it’s not some fancy term to solve a problem. And there’s multiple ways to solve that problem, too. And I think investigating that can be a really good way to stretch those lessons.
Eric Cross (29:32):
It almost sounds like an oxymoron, but this low-tech computer science strategy. Develop these skills and then transfer that once you have access to the tools.
Aryanna Trejo (29:39):
Yeah. Yeah. Absolutely. And I think it’s a good way for students who need kinesthetic means to start to understand something, or just different learning styles, to start transferring that over.
Eric Cross (29:53):
I probably have students in the classroom where those kinesthetic moving things would help be a great way—or WILL be a great way—for them to learn the principles and the fundamentals of coding. Instead of only giving the option to just do the computer, actually giving them some choice. Or giving them a way to be able to manipulate things. We’re still in the system of education that’s still very siloed. It’s been the same way for a hundred years. We got math and then we got science and we got English. I’m wondering, how can a teacher fit this into their daily lessons? And then, do you have any experiences or stories or things that you’ve seen, just really creative ways that you’ve seen teachers incorporate this? Outside the norm of, “This is a computer science class; we’re just gonna code.” But have you seen it branch out? In the trainings that you’ve done?
Aryanna Trejo (30:40):
I’ve seen examples of that. I’ve seen a teacher use Scratch to demonstrate different climates of California, and show the different climates. This past year for Hour of Code, my friend Amy—the one who helped me move to 9 Dots and at Code.org—she created this incredible tutorial called Poetry Bot. And it was a way to get students to match the mood of the poem to some of the elements that were happening in the stage. So they would have different backgrounds show up at different parts of the poem. When the words would show up, they would have different sprites show up. They would have, sometimes, sounds. Or the text would show up with different animations. So there are cross-curricular opportunities everywhere, if you can be creative enough to find them, or if you beg, borrow, steal from other educators who are doing this incredible work out there.
Eric Cross (31:36):
Yeah. I say this all the time, but I’m an educational DJ, not an MC.
Aryanna Trejo (31:44):
Oh yeah.
Eric Cross (31:45):
So MCs write their lyrics and DJs remix with things that other people have done.
Aryanna Trejo (31:48):
Absolutely.
Eric Cross (31:48):
I was like, I’m a DJ. I was like, all day. Sometimes I’ll write a lyric, once or twice, but most of the time I’m remixing things. So teachers, if you’ve been out there and you got an awesome interdisciplinary thing, or you’ve incorporated coding and it’s something that’s traditionally not seen, please send it to us. Share it with us.
Aryanna Trejo (32:03):
Yeah. And there are so many different places where you can find that. We have a forum for Code.org, but there’s also CSTA, the Computer Science Teachers Association. You can join your local chapter and get to know other computer science teachers out there.
Eric Cross (32:19):
I guess…to wrap up, I’ve been using Scratch programming, the MIT website. My students do the basic animated name, CS First, stuff. But over the years, I’ve noticed that my students are coming in with a higher level of sophistication in Scratch to where now the differentiation…some of my students are just doing very basic…and then I have other students who’ve created full-on video games with complex…like, you look at their Scratch page and it’s just an amazing amount of blocks and integrations and things that they have. Is there anything on Code.org that could be a next step? That takes them beyond, maybe like the visuals? And if so, what would be a good next step, to take students to advance them to another platform? There’s so many coding languages out there, I feel like. Or I might not even be thinking about that the right way.
Aryanna Trejo (33:20):
No, I think you are. You know, we have three different curricula out on our website right now. We have CS Fundamentals, which is probably more in line with what you’re talking about. We have a free CS Discoveries curriculum, and that is designed for, grades, I believe, 6 through 10. And that would be a really good entry point, for both teachers and for students.
Eric Cross (33:44):
There’s a lot of new stuff that I hadn’t seen yet, a few years ago.
Aryanna Trejo (33:49):
Yeah.
Eric Cross (33:49):
So I was really excited.
Aryanna Trejo (33:50):
One thing that I do know is that CS Discovery has just added an artificial intelligence slash machine-learning unit, that you can just pick up and give to your students. You don’t have to go in order with CS Discoveries, like you do with CS Principles. And I’ve gone through some of those lessons. They are really rad. And I would’ve loved to have learned that when I was in middle school or high school. So yeah, we’re constantly thinking of how we can make things one, relevant to our students, and two relevant to what’s going on in the world.
Eric Cross (34:20):
So would I be overselling it if I said, “If you go through this, you’ll be able to create an AI or a neural net to do all your homework”?
Aryanna Trejo (34:26):
You would be overselling it.
Eric Cross (34:27):
I would be? OK. So what I’ll do is, I’ll wait until the end of the school year, and then introduce it, and then by the time they’ve realized it’s not true, they’ll be eighth graders.
Aryanna Trejo (34:35):
There you go. Good old bait-and-switch.
Eric Cross (34:37):
You’re amazing. Thank you for serving teachers, and for being part of such a great organization that puts out great stuff. So much free curricula for teachers to be able to use. Especially nowadays we hunt and scour the internet for those types of things. And to be able to bring computer literacy into the classroom, and with your focus of serving communities of underrepresented groups, it feels good to know that not only is it high-quality material, but it’s also trying to raise everyone up. Because ultimately when we have more people trying to solve a common problem, we come up with better solutions. And I was talking to somebody who was a materials engineer somewhere in Europe, and he said one of the things about the U.S., As he was critiquing me on this flight, critiquing the U.S., He said, “One of the things about your country is that you have a heterogeneous group of people who, in a group, when you have multiple perspectives attacking a problem, you come up with more novel solutions.” He says, “That’s one of the great things, is that there’s not necessarily just a hive mind.” And I think that that’s one of the great things. We uplift different communities, and we uplift women, people of color, people who, have backgrounds that parents didn’t go to college but have these amazing qualities and strengths. And we put everybody focusing on the same issue. We come up with novel solutions that we wouldn’t have come up with if only select groups were trying to look at it and solve it. And so—.
Aryanna Trejo (36:22):
Yeah.
Eric Cross (36:23):
And we couldn’t do that without organizations like yours, that help empower teachers. So.
Aryanna Trejo (36:27):
Yeah! You really said it.
You’re coming to my classroom when you’re back in San Diego?
Aryanna Trejo (36:31):
Yeah! I totally will. Yeah. Let’s make it happen.
Eric Cross (36:34):
Last question. If you think back in your schooling, your own schooling, K through college, is there a person or a teacher that had a big impact on you? Or a learning experience that had an impact on you? And it could be, you know, positive or negative. But something that impacted you, even to this day, that stands out to you, that you remember?
Aryanna Trejo (36:56):
This is a big diversion from the topics that we’re talking about. But in grades 10 through 12, my drama teacher, Mr. Byler, who I still talk with, was such a huge impression on me. Really wonderful. And I couldn’t tell you the teaching moves that he did that were wonderful. I don’t know much about his management. But I can tell you that he gave me space to be confident, and grow into myself, through drama productions. They were high school productions, so they weren’t amazing. But I just really came into myself in high school, because I had the confidence to get on stage. And he was just such a wonderful mentor to all of us. So, props to Mr. Byler.
Eric Cross (37:39):
Shout out to Mr. Byler for creating space for Aryanna to fly! Thanks for making time, after your workday, to talk with us and to share Code.org with teachers.
Aryanna Trejo (37:54):
Of course. Happy to.
Eric Cross (37:59):
Thanks so much for joining me and Aryanna today. We want to hear more about you. If you have any great lessons or ways to keep student engagement high, please email us at stem@amplify.com. Make sure to click subscribe wherever you listen to podcasts. And join our brand new Facebook group, Science Connections: The Community for some extra content.
Stay connected!
Join our community and get new episodes every other Tuesday!
We’ll also share new and exciting free resources for your classroom every month.
Meet the guest
Aryanna is a member of the Code.org Professional Learning Team. Before joining Code.org, Aryanna led computer science professional development for K-6 teachers and served as an instructional coach for new educators. She also taught fourth and fifth grade in New York City and Los Angeles. In her spare time, Aryanna loves taking advantage of the California sunshine, creating wheel-thrown pottery, and hanging out with her dog Lola.
About Science Connections
Welcome to Science Connections! Science is changing before our eyes, now more than ever. So…how do we help kids figure that out? We will bring on educators, scientists, and more to discuss the importance of high-quality science instruction. In this episode, hear from our host Eric Cross about his work engaging students as a K-8 science teacher. Listen here!
You might also like:
Welcome, Utah K-8 reviewers!
1. Service Overview
As a provider of technology solutions to schools, Amplify’s commitment to data privacy and security is essential to our organization. This overview of Amplify’s Information Security Program describes physical, technical and administrative safeguards Amplify implements to protect student data in our care.
Company profile
Amplify Education, Inc. (Amplify) is a privately held company founded in 2000 as Wireless Generation. Amplify’s products include curriculum and instruction, assessment and intervention, professional development services and consulting services for K-12 education.
Service hosting
Amplify leverages Amazon Web Services (AWS) as its cloud hosting provider. Within AWS, Amplify utilizes Virtual Private Clouds (VPCs), which provide an isolated cloud environment within the AWS infrastructure. External network traffic to a VPC is managed via gateway and firewall rules, which are maintained in source code control to ensure that the configuration remains in compliance with Amplify security policy. In addition, the production VPCs and the development VPCs are isolated from each other and maintained in separate AWS accounts.
2. Policies & standards
Information security program
Amplify maintains a comprehensive information security program based on the National Institute of Standards and Technology (NIST) Cybersecurity Framework and the NIST SP 800-53 Rev. 5 family of information security controls. These provide a robust framework of best practices from which an organization can build its security policies and protocols based on identified risks, compliance requirements, and business needs. They cover critical practice areas, including access control, configuration management, incident response, security training, and other information security domains.
Governance
Amplify’s Information Security Committee has primary responsibility for the development, maintenance, and implementation of the Amplify information security program. The Information Security Committee is responsible for all information risk management activities within the company and is composed of technology, business and legal leaders from the organization. The Committee meets weekly and includes a dedicated VP of Information Security and a program manager to oversee, direct and coordinate its activities.
Policy execution
Adherence to the internal Amplify information security policy is an obligation of every Amplify employee. Amplify conducts a series of internal monitoring procedures to verify compliance with internal information security policies, and all Amplify employees undergo annual criminal background checks. In addition, any third-party contractors who come into contact with systems that may contain student data are contractually bound to maintain security and privacy of the data.
3. Data access controls
Access control
Amplify’s access control principles dictate that all student data we store on behalf of customers is only accessible to district-authorized users and to a limited set of internal Amplify users who may only access the data for purposes authorized by the district. Districts maintain control over their internal users and may grant or revoke access.
In limited circumstances and strictly for the purposes of supporting school districts and maintaining the functionality of systems, certain Amplify users may access Amplify systems with student data. All such access to student data by Amplify technicians or customer support requires both authentication and authorization to view the information.
Encryption
Data encryption is an important element of our protection of sensitive data at rest and in transit, and is reviewed and updated as appropriate annually, based on the latest standards and guidelines published by OWASP and NIST.
- In transit: Amplify encrypts all student data in transit over public connections, using Transport Layer Security (TLS), commonly known as SSL, using industry-standard protocols, ciphers, algorithms, and key sizes.
- At rest: Amplify encrypts student data at rest using the industry-standard AES-256 encryption algorithm.
4. Application security by design
Building the right roles into applications
Permissions within Amplify applications are designed on the principle that school districts control access to all student data. To facilitate this, Amplify applications are designed so that roles and permissions flow from the district to the individual user. For example, applications that offer schools a way to collect and report on assessment results have a web interface that requires district administrators to authorize individuals to view student data.
Security controls within applications are used to ensure that the desired privacy protections are technically enforced within the system. For example, if a principal is supposed to see only the data related to his or her school, Amplify ensures that, throughout the design and development process, our products restrict principals from seeing records for any students outside his or her school.
To make sure Amplify applications properly enforce permissions and roles, our development teams conduct reviews early in the design process to ensure roles and permissions are an essential component of the design of new applications.
Building security controls into applications
Amplify applications are also developed to minimize security vulnerabilities and ensure industry-standard application security controls are in place.
As part of the development process, Amplify has a set of application security standards that all applications handling student data are required to follow, including:
- Student data is secured using industry standard encryption when in transit between end-users and Amplify systems.
- Applications are built with password brute-force attack prevention.
- User sessions expire after a fixed period of time.
We also conduct manual and automated static code analysis as well as dynamic application security testing to preemptively identify vulnerabilities published by industry leaders such as OWASP (Open Web Application Security Project)
5. Proactive security
Risk assessments
Amplify periodically engages a security consulting firm to conduct risk assessments, aimed at identifying and prioritizing security vulnerabilities. The Information Security Committee coordinates remediation of the vulnerabilities. The security consulting firm also provides ongoing advice on current risks and advises on remediation of vulnerabilities and incident response.
Penetration testing
Amplify engages third-party firms to continually conduct application penetration testing. The purpose of this testing is to test for application security vulnerabilities in the production environment. We work with third party penetration testing program partners. Third-party testing involves a combination of automated and manual testing.
Vulnerability management
Amplify ensures that its systems are free of known vulnerabilities in several ways. Every production server runs vulnerability detection software that compares the installed software against a global database of known vulnerabilities. Secondly, we employ real time network monitoring that reports on any potentially malicious traffic. In addition, a third-party security firm continually reviews all of our system logs for potential security breaches. Lastly we continually test our applications against common malicious internet traffic. Violations in any of these areas will alert one of our operations teams, who are available around the clock.
In addition, Amplify participates in a private bug bounty program through HackerOne, working with the security community to find security vulnerabilities and support our efforts to keep our data and systems safe and secure.
Endpoint security
Access to production systems at Amplify is restricted to a limited set of internal Amplify users to support technical infrastructure, troubleshoot customer issues, or other purposes authorized by the district. In addition, Amplify requires multi-factor (MFA) authentication methods for access to all production systems. MFA involves a combination of something only the user knows and something only the user can access. For example, MFA for administrative access could involve entering a password as well as entering a one-time passcode sent via text message to the administrator’s mobile phone. The use of MFA reduces the possibility that an unauthorized individual could use a compromised password to access a system.
Infrastructure security
Network filtering technologies are used to ensure that production environments with student data are properly segmented from the rest of the network. Production environments only have limited external access to enable customers to use our web interfaces and other services. In addition, Amplify uses firewalls to ensure that development servers have no access to production environments.
Other measures that Amplify takes to secure its operational environment include system monitoring to detect anomalous activity that could indicate potential attacks and breaches.
Security training
At Amplify, we believe that protecting student data is the responsibility of all employees. We implemented a comprehensive information security awareness training program that all employees undergo upon initial hire, with an annual refresher training. We also provide information security training and annual social engineering tests for specific departments based on role.
6. Reactive security
Monitoring
Intrusion detection and prevention systems (IDS/IPS) are in place to analyze the network device logs, monitor the network and report anomalous activity for appropriate resolution.
Incident response
Amplify maintains a comprehensive Security Incident Response Policy Plan, which sets out roles, responsibilities and procedures for reporting, investigation, containment, remediation and notification of security incidents. Amplify works with reputable firms for incident response and digital forensics support, as well as annual table-top exercises in coordination with cybersecurity experts.
Business Continuity Planning and Disaster Recovery
Amplify maintains a comprehensive Business Continuity Planning and Disaster Recovery Plan (BCP/DR), to guide personnel in procedures to protect against business disruptions caused by an unexpected event. The plans and related operations processes are tested on a semiannual basis, with ensuing operations improvement and remediation work.
7. Compliance
Audits
In addition to penetration testing and other proactive security testing and monitoring outlined above, Amplify undergoes annual SOC 2 Type 2 examinations of controls relevant to security. The examination is formally known as a Type 2 Independent Service Auditor’s Report on Controls Relevant to Security. The most recent examination was conducted by Schellman & Company, LLC and covers the period from April 1, 2024–March 31, 2025. The report states that Amplify’s systems meet the criteria for the security principle and opine on management’s description of the organization’s system and the suitability of the design of controls to protect against unauthorized access, use, or modification.
The Type 2 report also opines on the operating effectiveness of controls over the review period. This means that our auditors confirmed that we have continued to follow established security controls over the period of time of the review.
Certifications
SOC 2: Amplify successfully completed the SOC 2 Type 2 examination of controls relevant to security (see above, under “Audits”).
Privacy
Amplify’s products are built to facilitate district compliance with applicable data privacy laws, including FERPA and state laws related to the collection, access and review and disclosure of student data. Amplify’s Customer Privacy Policy describes the types of information collected and maintained on behalf of our school district customers and limitations on use and sharing of that data.
8. Supporting documentation
In the course of customer security assessment, the following documentation can be provided by Amplify upon customers’ request:
- Penetration Testing Report
- Risk Assessment Report
- SOC 2 Type 2 Report
9. Report a vulnerability
To report a security vulnerability, click here.
Create transformation that lasts.
Embarking on educational change takes heart, intention, and determination. It also requires proven strategies and practical tools. With data, resources, and countless stories of successful implementations to guide us, we can take the first step toward true transformation together.
Principles for Educational Change Management
Whether you’re looking for transformative change in math, literacy, or science instruction, some essential principles apply across the board. As a teacher, administrator, or community leader, you’ll find these guiding principles can help you manage your new curriculum implementation and help each student reach their potential.
“This goes out to the interventionists, coaches, and administrators … support your staff. Lead staff trainings, provide push-in support, model and co-teach so that the staff will see that this is not ‘just another initiative.’ Remember, this is the start of a long, powerful journey. Take small steps, do them well, then use data to move on to the next small step.”
Leading instructional shifts across all disciplines
Make the shift to the Science of Reading.
Learn the key steps that will drive the success you need.
Change in math is different.
Managing change in math doesn’t have to mean starting over. It starts with a few simple shifts.
Be a science inspiration.
Intentional shifts help transform students into concerned global citizens ready to take on the world. Find out how.
Let data guide your transformation.
The right data at the right time is crucial in planning lasting instructional change. With specific metrics to guide your implementation, you’ll know exactly how to monitor your progress. Download our literacy assessment infographic as a model for the key data questions to ask at critical points in the school year.
Achieve implementation success.
Ready to navigate educational implementation with confidence? The following resources will help you discover practical strategies for decision-making, managing change, and engaging stakeholders.
Discover five steps to successful implementation.
Balancing decision-making, data collection, and transparent communication doesn’t have to be overwhelming. Discover the five essential steps to making implementation manageable.
Think like a leader.
Strategic leadership requires more than sharp management skills. Find out how the leadership brain model can help you, as a district leader, connect initiatives with your broader vision.
Turn plans into results.
Educational change requires intentional effort. Key leadership imperatives can provide the framework you need for effective implementation.
What district leaders are saying
“In the past we’ve adopted a resource and we’ve left it to the teachers and the buildings to use and to put into practice. I was determined that we needed to do more than just that for both our teachers and our students. That is really where…the leadership brain concept has come into play. [It] provided the framework and key questions that I needed so that I could reflect, process, and determine what was next throughout the first year of implementation.”
What district leaders are saying
“Through the guidance and collaboration of the Amplify Team, our stakeholders participated in thoughtful conversations, relevant hands-on learning, and the development of clear guidelines for moving forward [with Amplify CKLA]. This process led to the creation of our district commitments, which, together with the six leadership imperatives, remain central to the progress we continue to make today.”
What district leaders are saying
“[My advice to other leaders is to] stop trying to fix everything at once. Dig deep with systematic analysis to find your one high leverage problem; then build your entire system around solving it. You can have all the coaching and support in the world, but if you’re not focused on the right problem, those systems won’t translate to classroom impact.”
Educational leaders share their success.
Find out how educational leaders have transformed their districts through successful implementation, revealing the commitment and strategic approach that led to real academic improvements.
Change needs commitment.
Change is achievable when everyone commits to the process. See how one district turned collaboration into a successful implementation of Amplify CKLA.
Existing strengths need focused direction.
Strong district foundations require intentional focus. Learn how systematic analysis helped one district turn comprehensive resources into meaningful impact for teachers.
Shared responsibility transforms implementation.
Managing implementation alone limits success. Discover how one district leader used stakeholder mapping to create shared leadership and building-level ownership.
See implementation in action.
Learn how one district achieved positive test results across grades 1–5 within their first year of adopting Amplify CKLA.
Strategic change delivers results.
Results happen when change is managed strategically. Check out how one district turned thoughtful planning into successful Amplify CKLA adoption.
Curriculum evaluation leads to confident decisions.
Explore how one district implemented Amplify CKLA (after piloting seven different programs!) and achieved powerful kindergarten reading gains.
Regular communication fosters growth.
Structured coaching support transforms implementation outcomes. Find out how regular communication helped one district achieve consistency and sustained student growth with Amplify CKLA.
Preparation creates lasting results.
Comprehensive training creates the foundation for sustained success. Read about how strategic summer preparation and ongoing professional learning helped one county achieve significant academic improvements.
A closer look at grades 6–8
Amplify Science California is based on the latest research on teaching and learning and helps teachers deliver rigorous and riveting lessons through hands-on investigations, literacy-rich activities, and interactive digital tools that empower students to think, read, write, and argue like real scientists.
In the 6–8 classroom, this looks like students:
- Collecting evidence from a variety of sources.
- Making sense of evidence in a variety of ways.
- Formulating convincing scientific arguments.
Is your school implementing the domain model? Click here.
Program structure
Our cyclical lesson design ensures students receive multiple exposures to concepts through a variety of modalities. As they progress through the lessons within a unit, students build and deepen their understanding, increasing their ability to develop and refine complex explanations of the unit’s phenomenon.
It’s this proven program structure and lesson design that enables Amplify Science California to teach less, but achieve more. Rather than asking teachers to wade through unnecessary content, we designed our 6–8 program to address 100% of the California NGSS in fewer lessons than other programs.
Scope and sequence
Every year our grades 6–8 sequence consists of 9 units, with each unit containing 10–19 lessons. Lessons are written to last a minimum of 45-minutes, though teachers can expand or contract the timing to meet their needs.
Unit types
Each unit delivers three-dimensional learning experiences and engages students in gathering evidence from a rich collection of sources, while also serving a unique purpose.
In grades 6–8, there are three types of units:
- One unit is a launch unit.
- Three units are core units.
- Two units are engineering internships.
Launch units
Launch units are the first units taught in each year of Amplify Science California. The goal of the Launch unit is to introduce students to norms, routines, and practices that will be built on throughout the year, including argumentation, active reading, and using the program’s technology. For example, rather than taking the time to explain the process of active reading in every unit in a given year, it is explained thoroughly in the Launch unit, thereby preparing students to read actively in all subsequent units.
Core units
Core units establish the context of the unit by introducing students to a real-world problem. As students move through lessons in a Core unit, they figure out the unit’s anchoring phenomenon, gain an understanding of the unit’s disciplinary core ideas and science and engineering practices, and make linkages across topics through the crosscutting concepts. Each Core unit culminates with a Science Seminar and final writing activity.
Engineering Internship units
Engineering Internship units invite students to design solutions for real-world problems as interns for a fictional company called Futura. Students figure out how to help those in need, from tsunami victims in Sri Lanka to premature babies, through the application of engineering practices. In the process, they apply and deepen their learning from Core units.
Units at a glance
Microbiome
Domain: Life Science
Unit type: Launch
Student role: Microbiological researchers
Phenomenon: The presence of 100 trillion microorganisms living on and in the human body may keep the body healthy.
Metabolism
Domain: Life Science
Unit type: Core
Student role: Medical researchers
Phenomenon: Elisa, a young patient, feels tired all the time.
Metabolism Engineering Internship
Domains: Life Science, Engineering Design
Unit type: Engineering internship
Student role: Food engineers
Phenomenon: Designing health bars with different molecular compositions can effectively meet the metabolic needs of patients or rescue workers.
Traits and Reproduction
Domain: Life Science
Unit type: Core
Student role: Biomedical students
Phenomenon: Darwin’s bark spider offspring have different silk flexibility traits, even though they have the same parents.
Thermal Energy
Domain: Physical Science
Unit type: Core
Student role: Thermal scientists
Phenomenon: One of two proposed heating systems for Riverdale School will best heat the school.
Ocean, Atmosphere, and Climate
Domains: Earth and Space Science, Physical Science
Unit type: Core
Student role: Climatologists
Phenomenon: During El Niño years, the air temperature in Christchurch, New Zealand is cooler than usual.
Weather Patterns
Domains: Earth and Space Science, Physical Science
Unit type: Core
Student role: Forensic meteorologists
Phenomenon: In recent years, rainstorms in Galetown have been unusually severe.
Earth’s Changing Climate
Domains: Earth and Space Science, Life Science
Unit type: Core
Student role: Climatologists
Phenomenon: The ice on Earth’s surface is melting.
Earth’s Changing Climate Engineering Internship
Domains: Earth and Space Science, Engineering Design
Unit type: Engineering internship
Student role: Civil engineers
Phenomenon: Designing rooftops with different modifications can reduce a city’s impact on climate change.
Geology on Mars
Domain: Earth and Space Science
Unit type: Launch
Student role: Planetary geologists
Phenomenon: Analyzing data about landforms on Mars can provide evidence that Mars may have once been habitable.
Plate Motion
Domain: Earth and Space Science
Unit type: Core
Student role: Geologists
Phenomenon: Mesosaurus fossils have been found on continents separated by thousands of kilometers of ocean, even though the Mesosaurus species once lived all together.
Plate Motion Engineering Internship
Domains: Earth and Space Science, Engineering Design
Unit type: Engineering internship
Student role: Mechanical engineering interns
Phenomenon: Patterns in earthquake data can be used to design an effective tsunami warning system.
Rock Transformations
Domain: Earth and Space Science
Unit type: Core
Student role: Geologists
Phenomenon: Rock samples from the Great Plains and from the Rocky Mountains — regions hundreds of miles apart — look very different, but have surprisingly similar mineral compositions.
Phase Change
Domains: Physical Science, Earth and Space Science
Unit type: Core
Student role: Chemists
Phenomenon: A methane lake on Titan no longer appears in images taken by a space probe two years apart
Force and Motion Engineering Internship
Domains: Engineering Design, Physical Science
Unit type: Engineering internship
Student role: Mechanical engineering interns
Phenomenon: Designing emergency supply delivery pods with different structures can maintain the integrity of the supply pods and their contents.
Chemical Reactions
Domains: Physical Science, Life Science, Earth and Space Science
Unit type: Core
Student role: Forensic chemists
Phenomenon: A mysterious brown substance has been detected in the tap water of Westfield.
Populations and Resources
Domains: Life Science, Earth and Space Science
Unit type: Core
Student role: Biologists
Phenomenon: The size of the moon jelly population in Glacier Sea has increased.
Matter and Energy in Ecosystems
Domains: Life Science, Earth and Space Science, Physical Science
Unit type: Core
Student role: Ecologists
Phenomenon: The biodome ecosystem has collapsed.
Harnessing Human Energy
Domains: Physical Science, Earth and Space Science, Engineering Design
Unit type: Launch
Student role: Energy scientists
Phenomenon: Rescue workers can use their own human kinetic energy to power the electrical devices they use during rescue missions.
Force and Motion
Domain: Physical Science
Unit type: Core
Student role: Physicists
Phenomenon: The asteroid sample-collecting pod failed to dock at the space station as planned.
Phase Change Engineering Internship
Domains: Engineering Design, Physical Science
Unit type: Engineering internship
Student role: Chemical engineering interns
Phenomenon: Designing portable baby incubators with different combinations of phase change materials can keep babies at a healthy temperature.
Magnetic Fields
Domain: Physical Science
Unit type: Core
Student role: Physicists
Phenomenon: During a test launch, a spacecraft traveled much faster than expected.
Light Waves
Domains: Physical Science, Life Science, Earth and Space Science
Unit type: Core
Student role: Spectroscopists
Phenomenon: The rate of skin cancer is higher in Australia than in other parts of the world.
Earth, Moon, and Sun
Domains: Earth and Space Science, Physical Science
Unit type: Core
Student role: Astronomers
Phenomenon: An astrophotographer can only take pictures of specific features on the Moon at certain times.
Natural Selection
Domains: Life Science, Earth and Space Science
Unit type: Core
Student role: Biologists
Phenomenon: The newt population in Oregon State Park has become more poisonous over time.
Natural Selection Engineering Internship
Domains: Engineering Design, Life Science
Unit type: Engineering internship
Student role: Clinical engineers
Phenomenon: Designing malaria treatment plans that use different combinations of drugs can reduce drug resistance development while helping malaria patients.
Evolutionary History
Domains: Life Science, Earth and Space Science
Unit type: Core
Student role: Paleontologists
Phenomenon: A mystery fossil at the Natural History Museum has similarities with both wolves and whales.
Resources
Amplify’s Subprocessors
This page provides the current list of third party service providers that Amplify engages to help us provide our services and may have access to Personal Information of our customers (“Subprocessors”) as outlined in Amplify’s Customer Privacy Policy.
How to get notified of changes
Please use the “Subscribe to Updates” functionality at the top of the page to receive emails from Amplify regarding updates to the list of Subprocessors and/or changes to the information provided on this page. Should you choose not to use this functionality to receive email notifications, it is our expectation that you check the link regularly for any updates.
Our commitments regarding Service Providers
All of the Subprocessors listed below have a legitimate need to access Personal Information in order to provide their service to Amplify as a part of Amplify’s provision of the services to our customers. With regard to Subprocessors, Amplify commits to:
- Conduct due diligence on the data privacy and security measures of new Subprocessors before providing access to Personal Information and monitor on an annual basis thereafter. As part of this process, Amplify reviews the Subprocessor’s security documentation, practices, and posture to ensure alignment with Amplify’s information security program and standards;
- Enter into a written agreement which requires at least the same level of protection for Personal Information and individuals as set out in Amplify’s Customer Privacy Policy and our agreements with customers, as applicable, before providing access to Personal Information;
- Restrict the Subprocessor’s access to Personal Information to only what is necessary to fulfill our contractual obligations or as otherwise permitted under the agreements with our customers or under applicable data privacy laws; and
- Remain liable for any processing of Personal Information carried out by Subprocessors to the same extent we would be liable if performing the services ourselves.
Subprocessors
Amplify’s Subprocessors of Personal Information are:
| Subprocessor | Purpose | Location | Student Data | Educator Data |
| Amazon Web Services | Cloud hosting services | United States |  |
|
| Anthology (formerly Blackboard) | Video conferencing and attendee tracking for tutoring services | United States | |
|
| Boomi, Inc. | Data integration | United States | |
|
| Datadog | Performance and security monitoring | United States | |
|
| dbt Labs, Inc. | Run database queries | United States | |
|
| Egnyte, Inc. | Secure file exchange | United States | |
|
| Fivetran, Inc. | Database loading | United States | |
|
| Gainsight, Inc. | Customer support | United States | |
|
| Google, LLC | Cloud hosting services | United States | |
|
| Google, LLC (Looker) | Data warehouse analytics | United States | |
|
| HubSpot | Email delivery | United States | |
|
| MongoDB, Inc. | Database hosting | United States | |
|
| Salesforce | Customer relationship management | United States | |
|
| SchoolDay (formerly GG4L) | Secure rostering | United States | |
|
| Snowflake, Inc. | Database hosting | United States | |
|
| Talkdesk, Inc. | Customer support | United States | |
|
| Twilio, Inc. (Sendgrid) | Email delivery | United States | |
|
Updates
| Date of Change | Change | Notes |
| October 10, 2025 | Changed Blackboard to Anthology and GG4L to SchoolDay. Update MongoDB purpose. Added Datadog to the Students Subprocessor List. Created Educators Subprocessor List. | Anthology and SchoolDay updated their corporate branding. Added list of Educator Data Subprocessors to clarify which partners process educator data. |
| June 14, 2024 |
Removed Desmos Studio, PBC, Qualfon Data Services Group, LLC, and Zendesk, Inc. | These partners and services are no longer used for customer support. |
| July 27, 2023 |
Added Fivetran |
– |
| September 15, 2022 |
Corrected name of Desmos Studio, PBC. |
– |
| July 21, 2022 | Added Desmos Collective LLC, Google, MongoDB, Twilio, and Zendesk | These services support Mathigon.org and Desmos Classroom |
| July 20, 2022 | Added Qualfon Data Services Group, LLC | – |
| October 4, 2021 | Added Blackboard, Inc. | – |
| July 26, 2021 | Fishtown Analytics, Inc. renamed to dbt Labs, Inc. | – |
| June 17, 2021 | Updated with data warehousing and roster services providers | – |
| May 28, 2021 | Initial public posting. | – |
A closer look at grades 6–8 (domain)
Amplify Science is based on the latest research on teaching and learning and helps teachers deliver rigorous and riveting lessons through hands-on investigations, literacy-rich activities, and interactive digital tools that empower students to think, read, write, and argue like real scientists.
In the 6–8 classroom, this looks like students:
- Collecting evidence from a variety of sources.
- Making sense of evidence in a variety of ways.
- Formulating convincing scientific arguments.
Is your school implementing the domain model? Click here.
Program structure
Our cyclical lesson design ensures students receive multiple exposures to concepts through a variety of modalities. As they progress through the lessons within a unit, students build and deepen their understanding, increasing their ability to develop and refine complex explanations of the unit’s phenomenon.
It’s this proven program structure and lesson design that enables Amplify Science to teach less, but achieve more. Rather than asking teachers to wade through unnecessary content, we designed our 6–8 program to address 100% of the NGSS in fewer lessons than other programs.
Scope and sequence
Every year our grades 6–8 sequence consists of 9 units, with each unit containing 10–19 lessons. Lessons are written to last a minimum of 45-minutes, though teachers can expand or contract the timing to meet their needs.
Unit types
Each unit delivers three-dimensional learning experiences and engages students in gathering evidence from a rich collection of sources, while also serving a unique purpose.
In grades 6–8, there are three types of units:
- One unit is a launch unit.
- Three units are core units.
- Two units are engineering internships.
Launch units
Launch units are the first units taught in each year of Amplify Science. The goal of the Launch unit is to introduce students to norms, routines, and practices that will be built on throughout the year, including argumentation, active reading, and using the program’s technology. For example, rather than taking the time to explain the process of active reading in every unit in a given year, it is explained thoroughly in the Launch unit, thereby preparing students to actively read in all subsequent units.
Core units
Core units establish the context of the unit by introducing students to a real-world problem. As students move through lessons in a Core unit, they figure out the unit’s anchoring phenomenon, gain an understanding of the unit’s disciplinary core ideas and science and engineering practices, and make linkages across topics through the crosscutting concepts. Each Core unit culminates with a Science Seminar and final writing activity.
Engineering Internship units
Engineering Internship units invite students to design solutions for real-world problems as interns for a fictional company called Futura. Students figure out how to help those in need, from tsunami victims in Sri Lanka to premature babies, through the application of engineering practices. In the process, they apply and deepen their learning from Core units.
Units at a glance
Geology on Mars
Domain: Earth and Space Science
Unit type: Launch
Student role: Planetary geologists
Phenomenon: Analyzing data about landforms on Mars can provide evidence that Mars may have once been habitable.
Plate Motion
Domain: Earth and Space Science
Unit type: Core
Student role: Geologists
Phenomenon: Mesosaurus fossils have been found on continents separated by thousands of kilometers of ocean, even though the Mesosaurus species once lived all together.
Plate Motion Engineering Internship
Domain: Earth and Space Science
Unit type: Engineering internship
Student role: Mechanical engineering interns
Phenomenon: Patterns in earthquake data can be used to design an effective tsunami warning system.
Rock Transformations
Domain: Earth and Space Science
Unit type: Core
Student role: Geologists
Phenomenon: Rock samples from the Great Plains and from the Rocky Mountains — regions hundreds of miles apart — look very different, but have surprisingly similar mineral compositions.
Earth, Sun, and Moon
Domain: Earth and Space Science
Unit type: Core
Student role: Astronomers
Phenomenon: An astrophotographer can only take pictures of specific features on the Moon at certain times.
Ocean, Atmosphere, and Climate
Domain: Earth and Space Science
Unit type: Core
Student role: Climatologists
Phenomenon: During El Niño years, the air temperature in Christchurch, New Zealand is cooler than usual.
Weather Patterns
Domain: Earth and Space Science
Unit type: Core
Student role: Forensic meteorologists
Phenomenon: In recent years, rainstorms in Galetown have been unusually severe.
Earth’s Changing Climate
Domain: Earth and Space Science
Unit type: Core
Student role: Climatologists
Phenomenon: The ice on Earth’s surface is melting.
Earth’s Changing Climate Engineering Internship
Domain: Earth and Space Science
Unit type: Engineering internship
Student role: Civil engineers
Phenomenon: Designing rooftops with different modifications can reduce a city’s impact on climate change.
Microbiome
Domain: Life Science
Unit type: Launch
Student role: Microbiological researchers
Phenomenon: The presence of 100 trillion microorganisms living on and in the human body may keep the body healthy.
Metabolism
Domain: Life Science
Unit type: Core
Student role: Medical researchers
Phenomenon: Elisa, a young patient, feels tired all the time.
Metabolism Engineering Internship
Domain: Life Science
Unit type: Engineering internship
Student role: Food engineers
Phenomenon: Designing health bars with different molecular compositions can effectively meet the metabolic needs of patients or rescue workers.
Traits and Reproduction
Domain: Life Science
Unit type: Core
Student role: Biomedical students
Phenomenon: Darwin’s bark spider offspring have different silk flexibility traits, even though they have the same parents.
Populations and Resources
Domain: Life Science
Unit type: Core
Student role: Biologists
Phenomenon: The size of the moon jelly population in Glacier Sea has increased.
Matter and Energy in Ecosystems
Domain: Life Science
Unit type: Core
Student role: Ecologists
Phenomenon: What caused the mysterious crash of a biodome ecosystem?
Natural Selection
Domain: Life Science
Unit type: Core
Student role: Biologists
Phenomenon: The newt population in Oregon State Park has become more poisonous over time.
Natural Selection Engineering Internship
Domain: Life Science
Unit type: Engineering internship
Student role: Clinical engineers
Phenomenon: Designing malaria treatment plans that use different combinations of drugs can reduce drug resistance development while helping malaria patients.
Evolutionary History
Domain: Life Science
Unit type: Core
Student role: Paleontologists
Phenomenon: A mystery fossil at the Natural History Museum has similarities with both wolves and whales.
Harnessing Human Energy
Domain: Physical Science
Unit type: Launch
Student role: Energy scientists
Phenomenon: Rescue workers can use their own human kinetic energy to power the electrical devices they use during rescue missions.
Force and Motion
Domain: Physical Science
Unit type: Core
Student role: Physicists
Phenomenon: The asteroid sample-collecting pod failed to dock at the space station as planned.
Force and Motion Engineering Internship
Domain: Physical Science
Unit type: Engineering internship
Student role: Mechanical engineering interns
Phenomenon: Designing emergency supply delivery pods with different structures can maintain the integrity of the supply pods and their contents.
Magnetic Fields
Domain: Physical Science
Unit type: Core
Student role: Physicists
Phenomenon: During a test launch, a spacecraft traveled much faster than expected.
Thermal Energy
Domain: Physical Science
Unit type: Core
Student role: Thermal scientists
Phenomenon: One of two proposed heating systems for Riverdale School will best heat the school.
Phase Change
Domain: Physical Science
Unit type: Core
Student role: Chemists
Phenomenon: A methane lake on Titan no longer appears in images taken by a space probe two years apart.
Phase Change Engineering Internship
Domain: Physical Science
Unit type: Engineering internship
Student role: Chemical engineering interns
Phenomenon: Designing portable baby incubators with different combinations of phase change materials can keep babies at a healthy temperature.
Chemical Reactions
Domain: Physical Science
Unit type: Core
Student role: Forensic chemists
Phenomenon: A mysterious brown substance has been detected in the tap water of Westfield.
Light Waves
Domain: Physical Science
Unit type: Core
Student role: Spectroscopists
Phenomenon: The rate of skin cancer is higher in Australia than in other parts of the world.
Resources
A closer look at grades 6–8
Amplify Science is based on the latest research on teaching and learning and helps teachers deliver rigorous and riveting lessons through hands-on investigations, literacy-rich activities, and interactive digital tools that empower students to think, read, write, and argue like real scientists.
In the 6–8 classroom, this looks like students:
- Collecting evidence from a variety of sources.
- Making sense of evidence in a variety of ways.
- Formulating convincing scientific arguments.
Is your school implementing the domain model? Click here.
Program structure
Our cyclical lesson design ensures students receive multiple exposures to concepts through a variety of modalities. As they progress through the lessons within a unit, students build and deepen their understanding, increasing their ability to develop and refine complex explanations of the unit’s phenomenon.
It’s this proven program structure and lesson design that enables Amplify Science to teach less, but achieve more. Rather than asking teachers to wade through unnecessary content, we designed our 6–8 program to address 100% of the NGSS in fewer lessons than other programs.
Scope and sequence
Every year our grades 6–8 sequence consists of 9 units, with each unit containing 10–19 lessons. Lessons are written to last a minimum of 45-minutes, though teachers can expand or contract the timing to meet their needs.
Unit types
Each unit delivers three-dimensional learning experiences and engages students in gathering evidence from a rich collection of sources, while also serving a unique purpose.
In grades 6–8, there are three types of units:
- One unit is a launch unit.
- Three units are core units.
- Two units are engineering internships.
Launch units
Launch units are the first units taught in each year of Amplify Science. The goal of the Launch unit is to introduce students to norms, routines, and practices that will be built on throughout the year, including argumentation, active reading, and using the program’s technology. For example, rather than taking the time to explain the process of active reading in every unit in a given year, it is explained thoroughly in the Launch unit, thereby preparing students to read actively in all subsequent units.
Core units
Core units establish the context of the unit by introducing students to a real-world problem. As students move through lessons in a Core unit, they figure out the unit’s anchoring phenomenon, gain an understanding of the unit’s disciplinary core ideas and science and engineering practices, and make linkages across topics through the crosscutting concepts. Each Core unit culminates with a Science Seminar and final writing activity.
Engineering Internship units
Engineering Internship units invite students to design solutions for real-world problems as interns for a fictional company called Futura. Students figure out how to help those in need, from tsunami victims in Sri Lanka to premature babies, through the application of engineering practices. In the process, they apply and deepen their learning from Core units.
Units at a glance
Microbiome
Domain: Life Science
Unit type: Launch
Student role: Microbiological researchers
Phenomenon: The presence of 100 trillion microorganisms living on and in the human body may keep the body healthy.
Metabolism
Domain: Life Science
Unit type: Core
Student role: Medical researchers
Phenomenon: Elisa, a young patient, feels tired all the time.
Metabolism Engineering Internship
Domains: Life Science, Engineering Design
Unit type: Engineering internship
Student role: Food engineers
Phenomenon: Designing health bars with different molecular compositions can effectively meet the metabolic needs of patients or rescue workers.
Traits and Reproduction
Domain: Life Science
Unit type: Core
Student role: Biomedical students
Phenomenon: Darwin’s bark spider offspring have different silk flexibility traits, even though they have the same parents.
Thermal Energy
Domain: Physical Science
Unit type: Core
Student role: Thermal scientists
Phenomenon: One of two proposed heating systems for Riverdale School will best heat the school.
Ocean, Atmosphere, and Climate
Domains: Earth and Space Science, Physical Science
Unit type: Core
Student role: Climatologists
Phenomenon: During El Niño years, the air temperature in Christchurch, New Zealand is cooler than usual.
Weather Patterns
Domains: Earth and Space Science, Physical Science
Unit type: Core
Student role: Forensic meteorologists
Phenomenon: In recent years, rainstorms in Galetown have been unusually severe.
Earth’s Changing Climate
Domains: Earth and Space Science, Life Science
Unit type: Core
Student role: Climatologists
Phenomenon: The ice on Earth’s surface is melting.
Earth’s Changing Climate Engineering Internship
Domains: Earth and Space Science, Engineering Design
Unit type: Engineering internship
Student role: Civil engineers
Phenomenon: Designing rooftops with different modifications can reduce a city’s impact on climate change.
Geology on Mars
Domain: Earth and Space Science
Unit type: Launch
Student role: Planetary geologists
Phenomenon: Analyzing data about landforms on Mars can provide evidence that Mars may have once been habitable.
Plate Motion
Domain: Earth and Space Science
Unit type: Core
Student role: Geologists
Phenomenon: Mesosaurus fossils have been found on continents separated by thousands of kilometers of ocean, even though the Mesosaurus species once lived all together.
Plate Motion Engineering Internship
Domains: Earth and Space Science, Engineering Design
Unit type: Engineering internship
Student role: Mechanical engineering interns
Phenomenon: Patterns in earthquake data can be used to design an effective tsunami warning system.
Rock Transformations
Domain: Earth and Space Science
Unit type: Core
Student role: Geologists
Phenomenon: Rock samples from the Great Plains and from the Rocky Mountains — regions hundreds of miles apart — look very different, but have surprisingly similar mineral compositions.
Phase Change
Domains: Physical Science, Earth and Space Science
Unit type: Core
Student role: Chemists
Phenomenon: A methane lake on Titan no longer appears in images taken by a space probe two years apart
Force and Motion Engineering Internship
Domains: Engineering Design, Physical Science
Unit type: Engineering internship
Student role: Chemical engineering interns
Phenomenon: Designing portable baby incubators with different combinations of phase change materials can keep babies at a healthy temperature. Domains: Engineering Design, Physical Science
Chemical Reactions
Domains: Physical Science, Life Science, Earth and Space Science
Unit type: Core
Student role: Forensic chemists
Phenomenon: A mysterious brown substance has been detected in the tap water of Westfield.
Populations and Resources
Domains: Life Science, Earth and Space Science
Unit type: Core
Student role: Biologists
Phenomenon: The size of the moon jelly population in Glacier Sea has increased.
Matter and Energy in Ecosystems
Domains: Life Science, Earth and Space Science, Physical Science
Unit type: Core
Student role: Ecologists
Phenomenon: The biodome ecosystem has collapsed.
Harnessing Human Energy
Domains: Physical Science, Earth and Space Science, Engineering Design
Unit type: Launch
Student role: Energy scientists
Phenomenon: Rescue workers can use their own human kinetic energy to power the electrical devices they use during rescue missions.
Force and Motion
Domain: Physical Science
Unit type: Core
Student role: Physicists
Phenomenon: The asteroid sample-collecting pod failed to dock at the space station as planned.
Force and Motion Engineering Internship
Domains: Engineering Design, Physical Science
Unit type: Engineering internship
Student role: Chemical engineering interns
Phenomenon: Designing emergency supply delivery pods with different structures can maintain the integrity of the supply pods and their contents.
Magnetic Fields
Domain: Physical Science
Unit type: Core
Student role: Physicists
Phenomenon: During a test launch, a spacecraft traveled much faster than expected.
Light Waves
Domains: Physical Science, Life Science, Earth and Space Science
Unit type: Core
Student role: Spectroscopists
Phenomenon: The rate of skin cancer is higher in Australia than in other parts of the world.
Earth, Moon, and Sun
Domains: Earth and Space Science, Physical Science
Unit type: Core
Student role: Astronomers
Phenomenon: An astrophotographer can only take pictures of specific features on the Moon at certain times.
Natural Selection
Domains: Life Science, Earth and Space Science
Unit type: Core
Student role: Biologists
Phenomenon: The newt population in Oregon State Park has become more poisonous over time.
Natural Selection Engineering Internship
Domains: Engineering Design, Life Science
Unit type: Engineering internship
Student role: Clinical engineers
Phenomenon: Designing malaria treatment plans that use different combinations of drugs can reduce drug resistance development while helping malaria patients.
Evolutionary History
Domains: Life Science, Earth and Space Science
Unit type: Core
Student role: Paleontologists
Phenomenon: A mystery fossil at the Natural History Museum has similarities with both wolves and whales.
Resources
A closer look at grades 3–5
Amplify Science is based on the latest research on teaching and learning and helps teachers deliver age-appropriate, high-quality, literacy-rich instruction that enables students to take on the roles of scientists and engineers to solve real-world phenomena every day.
In the 3–5 classroom, this looks like students:
- Collecting evidence from a variety of sources.
- Making sense of evidence in a variety of ways.
- Formulating convincing scientific arguments.
Program structure
Our cyclical lesson design ensures students receive multiple exposures to concepts through a variety of modalities. As they progress through the lessons within a unit, students build and deepen their understanding, increasing their ability to develop and refine complex explanations of the unit’s phenomenon.
It’s this proven program structure and lesson design that enables Amplify Science to teach less, but achieve more. Rather than asking teachers to wade through unnecessary content, we designed our 3–5 program to address 100% of the NGSS in just 88 days.
Scope and sequence
Every year of our grades 3–5 sequence consists of 4 units and 88 lessons. Said another way, each unit contains 20 lessons plus two dedicated assessment days (a Pre-Unit Assessment and End-of-Unit Assessment).
Lessons for grades 3–5 are written to last a minimum of 60 minutes, though teachers can expand or contract the timing to meet their needs.
Unit types
Each unit delivers three-dimensional learning experiences and engages students in gathering evidence from a rich collection of sources, while also emphasizing a particular science and engineering practice.
In grades 3–5:
- One unit emphasizes the practice of investigation.
- One unit emphasizes the practice of modeling.
- One unit emphasizes the practice of engineering design.
- One unit emphasizes the practice of argumentation.
Investigation Units
Investigation units focus on the process of strategically developing investigations and gathering data to answer questions. Students are first asked to consider questions about what happens in the natural world and why, and are then involved in designing and conducting investigations that produce data to help answer those questions.
Modeling Units
Modeling units provide extra support to students engaging in the practice of modeling. Students use physical models, investigate with computer models, and create their own diagrams to help them visualize what might be happening on the nanoscale.
Engineering Design Units
Engineering design units provide opportunities for students to solve complex problems by applying science principles to the design of functional solutions, and iteratively testing those solutions to determine how well they meet preset criteria.
Argumentation units
Argumentation units provide students with regular opportunities to explore and discuss available evidence, time and support to consider how evidence may be leveraged in support of claims, and independence that increases as they mount written arguments in support of their claims.
Units at a glance
Balancing Forces
Domain: Physical Science
Unit type: Modeling
Student role: Engineers
Phenomenon: The town of Faraday is getting a new train that floats above its tracks.
Inheritance and Traits
Domains: Life Science
Unit type: Investigation
Student role: Wildlife biologists
Phenomenon: An adopted wolf in Graystone National Park (“Wolf 44”) has some traits that appear similar to one wolf pack in the park and other traits that appear to be similar to a different wolf pack.
Environments and Survival
Domains: Life Science, Engineering Design
Unit type: Engineering design
Student role: Biomimicry engineers
Phenomenon: Over the last 10 years, a population of grove snails has changed: The number of grove snails with yellow shells has decreased, while the number of snails with banded shells has increased.
Weather and Climate
Domains: Earth and Space Science, Engineering Design
Unit type: Argumentation
Student role: Meteorologists
Phenomenon: Three different islands, each a contender for becoming an Orangutan reserve, experience different weather patterns.
Energy Conversions
Domains: Physical Science, Earth and Space Science, Engineering Design
Unit type: Engineering design
Student role: System engineers
Phenomenon: The fictional town of Ergstown experiences frequent blackouts.
Vision and Light
Domain: Physical Science, Life Science, Engineering Design
Unit type: Investigation
Student role: Conservation biologists
Phenomenon: The population of Tokay geckos in a rain forest in the Philippines has decreased since the installation of new highway lights.
Earth’s Features
Domain: Earth and Space Science
Unit type: Argumentation
Student role: Geologists
Phenomenon: A mysterious fossil is discovered in a canyon within the fictional Desert Rocks National Park.
Waves, Energy, and Information
Domains: Physical Science, Life Science, Earth and Space Science, Engineering Design
Unit type: Modeling
Student role: Marine scientists
Phenomenon: Mother dolphins in the fictional Blue Bay National Park seem to be communicating with their calves when they are separated at a distance underwater.
Patterns of Earth and Sky
Domains: Physical Science, Earth and Space Science
Unit type: Investigation
Student role: Astronomers
Phenomenon: An ancient artifact depicts what we see in the sky at different times — the sun during the daytime and different stars during the nighttime — but it is missing a piece.
Modeling Matter
Domain: Physical Science
Unit type: Modeling
Student role: Food scientists
Phenomenon: Chromatography is a process for separating mixtures. Some solids dissolve in a salad dressing while others do not. Oil and vinegar appear to separate when mixed in a salad dressing.
The Earth System
Domains: Earth and Space Science, Physical Science, Engineering Design
Unit type: Engineering Design
Student role: Water resource engineers
Phenomenon: East Ferris, a city on one side of the fictional Ferris Island, is experiencing a water shortage, while West Ferris is not.
Ecosystem Restoration
Domains:Physical Science, Life Science, Earth and Space Science, Engineering Design
Unit type: Argumentation
Student role: Ecologists
Phenomenon: The jaguars, sloths, and cecropia trees in a reforested section of a Costa Rican rain forest are not growing and thriving.
Resources
A closer look at grades 6–8 (domain)
Amplify Science California is based on the latest research on teaching and learning and helps teachers deliver rigorous and riveting lessons through hands-on investigations, literacy-rich activities, and interactive digital tools that empower students to think, read, write, and argue like real scientists.
In the 6–8 classroom, this looks like students:
- Collecting evidence from a variety of sources.
- Making sense of evidence in a variety of ways.
- Formulating convincing scientific arguments.
Is your school implementing the integrated model? Click here.
Program structure
Our cyclical lesson design ensures students receive multiple exposures to concepts through a variety of modalities. As they progress through the lessons within a unit, students build and deepen their understanding, increasing their ability to develop and refine complex explanations of the unit’s phenomenon.
It’s this proven program structure and lesson design that enables Amplify Science California to teach less, but achieve more. Rather than asking teachers to wade through unnecessary content, we designed our 6–8 program to address 100% of the California NGSS in fewer lessons than other programs.
Scope and sequence
Every year of our grades 6–8 sequence consists of 9 units, with each unit containing 10–19 lessons. Lessons are written to last a minimum of 45 minutes, though teachers can expand or contract the timing to meet their needs.
Unit types
Each unit delivers three-dimensional learning experiences and engages students in gathering evidence from a rich collection of sources, while also serving a unique purpose.
In grades 6–8, there are three types of units:
- One unit is a launch unit.
- Three units are core units.
- Two units are engineering internships.
Launch units
Launch units are the first units taught in each year of Amplify Science California. The goal of the Launch unit is to introduce students to norms, routines, and practices that will be built on throughout the year, including argumentation, active reading, and using the program’s technology. For example, rather than taking the time to explain the process of active reading in every unit in a given year, it is explained thoroughly in the Launch unit, thereby preparing students to actively read in all subsequent units.
Core units
Core units establish the context of the unit by introducing students to a real-world problem. As students move through lessons in a Core unit, they figure out the unit’s anchoring phenomenon, gain an understanding of the unit’s disciplinary core ideas and science and engineering practices, and make linkages across topics through the crosscutting concepts. Each Core unit culminates with a Science Seminar and final writing activity.
Engineering Internship units
Engineering Internship units invite students to design solutions for real-world problems as interns for a fictional company called Futura. Students figure out how to help those in need, from tsunami victims in Sri Lanka to premature babies, through the application of engineering practices. In the process, they apply and deepen their learning from Core units.
Units at a glance
Geology on Mars
Domain: Earth and Space Science
Unit type: Launch
Student role: Planetary geologists
Phenomenon: Analyzing data about landforms on Mars can provide evidence that Mars may have once been habitable.
Plate Motion
Domain: Earth and Space Science
Unit type: Core
Student role: Geologists
Phenomenon: Mesosaurus fossils have been found on continents separated by thousands of kilometers of ocean, even though the Mesosaurus species once lived all together.
Plate Motion Engineering Internship
Domain: Earth and Space Science
Unit type: Engineering internship
Student role: Mechanical engineering interns
Phenomenon: Patterns in earthquake data can be used to design an effective tsunami warning system.
Rock Transformations
Domain: Earth and Space Science
Unit type: Core
Student role: Geologists
Phenomenon: Rock samples from the Great Plains and from the Rocky Mountains — regions hundreds of miles apart — look very different, but have surprisingly similar mineral compositions.
Earth, Sun, and Moon
Domain: Earth and Space Science
Unit type: Core
Student role: Astronomers
Phenomenon: An astrophotographer can only take pictures of specific features on the Moon at certain times.
Ocean, Atmosphere, and Climate
Domain: Earth and Space Science
Unit type: Core
Student role: Climatologists
Phenomenon: During El Niño years, the air temperature in Christchurch, New Zealand is cooler than usual.
Weather Patterns
Domain: Earth and Space Science
Unit type: Core
Student role: Forensic meteorologists
Phenomenon: In recent years, rainstorms in Galetown have been unusually severe.
Earth’s Changing Climate
Domain: Earth and Space Science
Unit type: Core
Student role: Climatologists
Phenomenon: The ice on Earth’s surface is melting.
Earth’s Changing Climate Engineering Internship
Domain: Earth and Space Science
Unit type: Engineering internship
Student role: Civil engineers
Phenomenon: Designing rooftops with different modifications can reduce a city’s impact on climate change.
Microbiome
Domain: Life Science
Unit type: Launch
Student role: Microbiological researchers
Phenomenon: The presence of 100 trillion microorganisms living on and in the human body may keep the body healthy.
Metabolism
Domain: Life Science
Unit type: Core
Student role: Medical researchers
Phenomenon: Elisa, a young patient, feels tired all the time.
Metabolism Engineering Internship
Domain: Life Science
Unit type: Engineering internship
Student role: Food engineers
Phenomenon: Designing health bars with different molecular compositions can effectively meet the metabolic needs of patients or rescue workers.
Traits and Reproduction
Domain: Life Science
Unit type: Core
Student role: Biomedical students
Phenomenon: Darwin’s bark spider offspring have different silk flexibility traits, even though they have the same parents.
Populations and Resources
Domain: Life Science
Unit type: Core
Student role: Biologists
Phenomenon: The size of the moon jelly population in Glacier Sea has increased.
Matter and Energy in Ecosystems
Domain: Life Science
Unit type: Core
Student role: Ecologists
Phenomenon: What caused the mysterious crash of a biodome ecosystem?
Natural Selection
Domain: Life Science
Unit type: Core
Student role: Biologists
Phenomenon: The newt population in Oregon State Park has become more poisonous over time.
Natural Selection Engineering Internship
Domain: Life Science
Unit type: Engineering internship
Student role: Clinical engineers
Phenomenon: Designing malaria treatment plans that use different combinations of drugs can reduce drug resistance development while helping malaria patients.
Evolutionary History
Domain: Life Science
Unit type: Core
Student role: Paleontologists
Phenomenon: A mystery fossil at the Natural History Museum has similarities with both wolves and whales.
Harnessing Human Energy
Domain: Physical Science
Unit type: Launch
Student role: Energy scientists
Phenomenon: Rescue workers can use their own human kinetic energy to power the electrical devices they use during rescue missions.
Force and Motion
Domain: Physical Science
Unit type: Core
Student role: Physicists
Phenomenon: The asteroid sample-collecting pod failed to dock at the space station as planned.
Force and Motion Engineering Internship
Domain: Physical Science
Unit type: Engineering internship
Student role: Mechanical engineering interns
Phenomenon: Designing emergency supply delivery pods with different structures can maintain the integrity of the supply pods and their contents.
Magnetic Fields
Domain: Physical Science
Unit type: Core
Student role: Physicists
Phenomenon: During a test launch, a spacecraft traveled much faster than expected.
Thermal Energy
Domain: Physical Science
Unit type: Core
Student role: Thermal scientists
Phenomenon: One of two proposed heating systems for Riverdale School will best heat the school.
Phase Change
Domain: Physical Science
Unit type: Core
Student role: Chemists
Phenomenon: A methane lake on Titan no longer appears in images taken by a space probe two years apart.
Phase Change Engineering Internship
Domain: Physical Science
Unit type: Engineering internship
Student role: Chemical engineering interns
Phenomenon: Designing portable baby incubators with different combinations of phase change materials can keep babies at a healthy temperature.
Chemical Reactions
Domain: Physical Science
Unit type: Core
Student role: Forensic chemists
Phenomenon: A mysterious brown substance has been detected in the tap water of Westfield.
Light Waves
Domain: Physical Science
Unit type: Core
Student role: Spectroscopists
Phenomenon: The rate of skin cancer is higher in Australia than in other parts of the world.
Resources
What my wedding taught me about choosing curriculum
Before my wedding over 20 years ago, my mom offered me a bit of advice: Choose a wedding photographer that you like. She didn’t mean one who’d win a Pulitzer for her work covering our special day. What she did mean was this: Make sure you like their personality, because you will spend a lot of time with them on your wedding day—maybe even more time than you’ll spend with your future spouse.
Why am I talking about my wedding in a blog about education?
Because choosing a curriculum company is like choosing a wedding photographer. You are not just purchasing a stack of books—you are starting a relationship with a company that will extend far beyond the initial purchase.
Here’s why I think the Amplify team are the education equivalent of ideal wedding photographers.
When our team decided to pilot Core Knowledge Language Arts (CKLA) 3rd Edition as our reading and writing curriculum, I soon began working with the Amplify CKLA pilot team because I knew our classroom teachers needed to be trained quickly. I created a timeline, outlined action steps, and noted questions about the process. I was confident in the product and had a sense of what needed to happen, but it felt like a lot.
At our first meeting, the pilot team presented a detailed brochure. What a comfort it was to read, “Your district’s Amplify CKLA pilot specialist will guide you through every step of the pilot support process.”
Sure enough, Amplify’s live in-person CKLA training was invaluable. The teachers got so excited about the new product that they literally cheered.
Because of our complex pilot schedule, I wanted to make sure our primary students weren’t leaving the year with gaps in their learning. The CKLA pilot team worked closely with me to create a unique unit that would leave no holes in student learning.
After six weeks of piloting the product, a team of experienced CKLA pilot team coaches visited all our pilot classrooms. They affirmed the teachers in their work toward CKLA implementation. They highlighted strengths in classrooms and celebrated the use of the product in our district. The meeting after school was joyful.
The CKLA pilot team also gave our teachers a crucial tip: Because you can’t memorize the lesson, it’s ok to teach with the manual in your hand. Teachers still do this, and we continue to compliment them if we see it during walk-throughs.
The online pilot tool kit provided all of the other resources we might need. This included a Q&A section in which teachers could enter questions as they came up, and receive a response from the support team quickly. I breathed easier during our pilot knowing that CKLA was caring for us.
After our school board officially adopted CKLA 3rd Edition, we transitioned from the CKLA pilot team to the Onboarding Support and Customer Success team. Leaving the pilot team felt like losing a friend, but I trusted Amplify and knew the new team would be just as strong.
The brochure for the development plan confirmed that we would remain in good hands. It read: “This custom professional development package is designed to support teachers, schools, and district leaders in helping teachers feel confident using CKLA in their classrooms. Our professional development opportunities go far beyond initial product training and take participants through different stages of learning.”
At our Launch training in August, teachers learned the core features, rationale, and Science of Reading research, and had time to dive into the CKLA materials. At the Strengthen trainings in October and March, teachers learned about additional tools to deepen their knowledge, planning, and use of the materials. At the Coach sessions, an Amplify coach visited every school, which included meeting with teachers during planning time, visiting classrooms and offering supportive feedback, and modeling lessons.
After each training session, a CKLA team met with me to discuss the success of the training and talk about the feedback from teachers and my next steps to support them in their implementation. Throughout the process, my goal was to help teachers feel successful and confident using this new tool, and Amplify supported me every step of the way.
In addition to the responsive customer service, Amplify also offers plenty of online tools. The PD Library is continually adding resources, while Amplify podcasts highlight the latest research and insights on language comprehension, reading comprehension, and so much more. Amplify also just added a series of instructional routine modeling videos that quickly demonstrate the best practices found in CKLA. The support systems are varied and always developing, yet never overwhelming.
If you’re in the market for a new reading curriculum, take my mom’s advice: Pick the one you love spending time with. Trust me—Amplify is the curriculum you’ll want by your side all day, every day.
Science of Reading:
A glossary
The Science of Reading reflects decades of research on how children best learn to read and which instructional practices best support their journey. Understanding common Science of Reading definitions can help fast-track your instruction, so we’ve put together this glossary as a starting point.
Common Science of Reading terms
Some of the most important terms for building your understanding of the Science of Reading:
Alphabetic principle: The understanding that specific sounds can be mapped onto specific letters
Biliteracy: The ability to communicate effectively in two different languages
Composition: The creation or organization of a written piece, short or long
Comprehension: The ability to understand what is written or said
Decoding: Translating a word from print to speech by understanding sound-spelling correspondences
Domain-specific knowledge: Understanding of the key principles in a specific subject area (such as scientific principles, poetry conventions)
Domain-specific vocabulary: Words key to understanding a specific subject area (such as scientific terms, poetic terms, technical terms)
Dyslexia: A language-based learning disorder or set of learning differences that makes it difficult to learn to read, write, or spell
Encoding: Translating a word from speech to print by understanding sound-spelling correspondences
Fluency: The ability to read a text with accuracy, speed, and expression
Inferences: Conclusions drawn through reasoning, without their being stated directly in a text
Learning differences: The unique ways in which brains can process information and the different rates at which they do it
Mental model: A general idea or structure of information that can be applied to many texts
Metacognition: Being mindful of one’s own thinking processes, including using knowledge of a given task, knowledge of cognitive strategies, and knowledge of one’s self, to successfully learn
Morphology: The study of word parts and how words are formed
MTSS (Multi-Tiered Systems of Support): A comprehensive framework designed to provide systematic and differentiated support to all students
Phoneme: The smallest unit of sound that distinguishes one word from another
Phonemic awareness: The ability to identify and work with individual sounds (phonemes) within a word
Phonics: Teaching the relationship between the sounds in oral language and the letters in written language
Reading Rope: A visual representation of the way decoding and comprehension skills work together in the brain of a skilled reader
Reasoning: The ability to apply knowledge based on new or existing information to comprehend the meaning of a passage
Science of Reading: The body of ongoing scientific research about how the brain works when one is learning to read, and how reading is best taught
Science of Writing: The body of ongoing scientific research about how the brain works when one is learning to write, and how writing is best taught
Sight recognition: The ability to recognize a written word without having to sound it out (also called word recognition)
Simple View of Reading: A framework that explains how word recognition and language comprehension work together to produce skilled reading
Simple View of Writing: A framework that explains how transcription and composition skills work together to produce skilled writing
Tier 1 instruction: Core grade-level instruction
Tier 2 instruction: Additional support for small groups of students to reinforce grade-level instruction
Tier 3 instruction: Intensive, more individualized intervention
Transcription: The process of converting speech into written text
Vocabulary: The quantity and quality of words a student knows
Word recognition: The ability to recognize a written word without having to sound it out (also called sight recognition)
Your guide to getting started with the Science of Reading
Looking for more grounding in the Science of Reading? Download our free ebook.
Welcome Reviewers, to Amplify Desmos Math!
Amplify Desmos Math thoughtfully combines conceptual understanding, procedural fluency, and application. Each lesson is designed to tell a story by posing problems that invite a variety of approaches before guiding students to synthesize their understanding of the learning goals.
Scroll to learn more about the program and explore sample materials.
About the program
We believe in math that motivates. Our structured approach to problem-based learning builds on students’ curiosity to develop lasting grade-level understandings for all students.
The program thoughtfully combines conceptual understanding, fluency, and application, motivating students with interesting problems they are eager to solve. Teachers can spend more time where it’s most impactful: creating a collaborative classroom of learners.
A powerful suite of math resources
Amplify Desmos Math combines the best of problem-based lessons, intervention, personalized practice, and assessments into a coherent and engaging experience for both students and teachers.
Screening and progress monitoring
mCLASS® Assessments, along with daily formative checks, measure not only what students know, but also how they think. The asset-based assessment system provides teachers with targeted, actionable insights, linked to core instruction and intervention resources.
Core instruction
Amplify Desmos Math lessons provide a structured approach to problem-based learning, helping teachers create a collaborative math community with students at its center. Each lesson systematically builds on students’ curiosity to develop lasting grade-level understandings for all students.
Differentiation and intervention
Integrated resources like Mini-Lessons, Fluency Practice, and Math Adventures provide targeted intervention on a specific concept or skill connected to daily instruction. Extensions are also available to stretch students’ understanding.
Boost™ Personalized Learning activities help students access grade-level math through engaging, independent digital practice. Responsive Feedback™ adjusts to students’ work, providing item-level adaptivity to further support their learning.
An approach that supports teachers
Clear, step-by-step instructional moves help teachers plan and teach student-centered lessons that use student thinking to differentiate instruction and guide to grade-level understanding. They include:
- Guidance on what to listen for and how to respond.
- Clear learning objectives to keep learning on track for each activity and lesson.
- Daily reinforcement activities to provide direct instruction when needed.
A structured approach to problem-based learning
Problem-based learning asks students to make sense of and think strategically about mathematically interesting problems. This approach allows students’ ideas to take
center stage, so they are active and engaged in their learning process. Teachers are able to hear and respond to student thinking in real time, guiding and differentiating instruction right in the moment.
Moving from “I do, We do, You do” to “You do, We do, I do”
Lessons begin by activating student’s prior knowledge and curiosity, inviting them to explore the math, collaborate, and refine their thinking. By focusing on developing student thinking first, teachers can better connect ideas, guide learning, and synthesize learning objectives.
Lessons that are rigorous and delightful
Every lesson in Amplify Desmos Math is designed to put students at the center of their learning. Utilizing research-based best practices, students engage in meaningful work based on rich problems and real-world experiences.
Warm-Up
Lessons begin by inviting every student to contribute to the mathematical discussion. Instructional routines are often used to build fluency, set the context, activate prior knowledge, or highlight a strategy that may be helpful in the lesson.
Rich learning activities
Math knowledge is built through experiences and meaningful interactions. Students notice, wonder, explore, calculate, predict, measure, explain their thinking, use math to settle disputes, create challenges for their classmates, and more. Teachers serve as a guide, using a Launch, Monitor, Connect framework:
- Launch: Teachers offer a short introduction to the problem or challenge
- Monitor: As students work individually, in pairs, or in groups, teachers ask questions and provide support to move student thinking closer to the intended math goal.
- Connect: Teachers connect student ideas to the Key Takeaway of the activity to help students synthesize and solidify the big ideas.
Synthesis
Teachers ensure that students end the lesson with accurate and enduring understandings of the math goal through synthesis of student ideas, explicit instruction, and reflection.
A short Show What You Know assessment allows students to show what they know about the learning goals of the lesson and reveal what they are still learning.
Differentiation and practice
Lasting understanding requires reinforcement. Every lesson offers Lesson Practice instructional recommendations to Support, Strengthen, and Stretch learning.
Print for every lesson with engaging digital experiences
Whether in print or digital form, engaging interactions enable students and teachers to openly exchange ideas. Each lesson includes student print materials, interactive teacher Presentation Screens, and digital resources for practice and differentiation. Some lessons also use manipulatives or provide options for students to use devices individually or in pairs. Device recommendations for student use are age-appropriate, with more frequent usage in middle and high school.
Demo access
Please login to the digital platform to experience our full program as part of your review. In order to access the digital platform, you’ll need to log into using your unique login credentials below.
- Click the orange button below to access the platform.
- Click “Log in with Amplify.”
- Enter the username and password:
- Username:
- Password:
- View the video for helpful platform navigation tips.
Assessments
By starting with what students already know, Amplify Desmos Math helps build a strong foundation for success to guide and support future learning. Teachers are empowered to transform every classroom into an engaged math community that invites, values, and develops student thinking. With explicit guidance on what to look for and how to respond, teachers can effectively support students as they develop their understanding.
Program assessments
A variety of performance data in Amplify Desmos Math provides evidence of student learning while helping students bolster their skills and understanding.
Unit-Level Assessments
Our embedded unit assessments offer key insights into students’ conceptual understanding of math. These assessments provide regular, actionable information about how students are thinking about and processing math, with both auto-scoring and in-depth rubrics that help teachers anticipate and respond to students’ learning needs.
Lesson-Level Assessments
Amplify Desmos Math lessons are centered around sense-making and in-the-moment feedback. Daily moments of assessment provide valuable evidence of learning for both the teacher and student.
Data and reporting
Amplify Desmos Math provides teachers and administrators with unified reporting and insights so that educators have visibility into what students know about grade-level math—and can plan instruction accordingly for the whole class, small groups, and individual students.
Assessment reports
Reporting functionality integrates unit assessments, lesson assessments, personalized learning, Benchmark assessments, and Progress Monitoring for a comprehensive look at student learning.
Our reports show proficiency and growth by domain, cluster, standard, and priority concept using performance data from unit assessments. Then our reports highlight areas of potential student need to allow teachers to modify their instruction and target differentiated support.
At-a-glance views of unit-level assessment results inform your instructional planning, and you can also drill down to item-level analysis.
Standards reports
Our standards report allows you to monitor proficiency at the class and individual student levels. Proficiency and growth are shown by domain, cluster, standard, and priority concepts. Areas of potential student need are highlighted to allow teachers to modify their instruction and target differentiated support.
Administrator reports
Amplify Desmos Math provides a complete picture of student, class, and district performance, allowing administrators to implement instructional and intervention plans.
- Track student, class, and district performance with usage, completion, and assessment data.
- Accurately group students and classes with the Benchmark and Progress Monitoring data of mCLASS Assessments and allow teachers to reliably implement and track the progress of Tier 2 and Tier 3 intervention.
- Provide one data-driven solution that educators can rely on for high-quality math instruction.
Differentiation and intervention
Amplify Desmos Math views differentiation as an ongoing process where teachers are both reactive and proactive to student needs, ensuring that all students have clear pathways to proficiency. Through rich data and teacher support, Amplify Desmos Math uses flexible categories of intervention and enrichment that adjust daily according to student thinking.
In-the-moment differentiation supports are available for every lesson, both digitally and in the print Teacher Edition.
In-lesson differentiation
Within every lesson activity, teachers can use the suggestions in the Differentiation Teacher Moves table to provide in-the-moment instructional support while students are engaged in the work of the lesson. This table can help teachers anticipate the ways students may approach the activity, and provides prompts that they can use during the lesson to Support, Strengthen, and Stretch individual students in their thinking. Teachers are provided with clear student actions and understanding to look for, each matched with immediately usable suggestions for how to respond to the student thinking illustrated in each row of the table. In addition to using these suggestions in the moment as teachers monitor student work, teachers can review the Differentiation table in advance to help them anticipate how students are likely to approach the activity.
Differentiation: Beyond the Lesson
Teachers are provided with recommendations for resources to use with each group of students needing support, strengthening, and stretching after each lesson. Support, Strengthen, and Stretch resources include:
- Mini-Lessons: 15-minute, small-group direct instruction lessons targeted to a specific concept or skill
- Item Banks: Space for teachers to create practice and assessments by using filters and searching for standards, summative-style items, and more
- Fluency Practice: Adaptive, personalized practice built out for basic operations and more
- Centers (K–5): Lesson-embedded routines and practice for students that are vertically aligned across grade levels
- Extensions: Lesson-embedded Teacher Moves including possible stretch questions and activities for students
- Lesson Practice: Additional practice problems support every lesson
- Math Adventures: Strategy-based math games where students engage with math concepts and practice skills in a fun digital environment
Multilingual/English Learner supports
Supports for multilingual/English learners (ML/ELs) are called out at intentiSupports for multilingual/English learners (ML/ELs) are called out at intentional points within each lesson. These suggested supports are specific, targeted actions that are beneficial for ML/ELs. They often describe a modification to increase access to the task or provide support with contextual or mathematical language development that can often be helpful to all learners. ML/EL supports may also be attached to Math Language Routines.onal points within each lesson. These suggested supports are specific, targeted actions that are beneficial for ML/ELs. They often describe a modification to increase access to the task or provide support with contextual or mathematical language development that can often be helpful to all learners. ML/EL supports may also be attached to Math Language Routines.
Math Language Development
Every lesson in Amplify Desmos Math includes opportunities for all students to develop mathematical language as they experience the content. Amplify Desmos Math purposefully progresses language development from lesson to lesson and across units by supporting students in making their arguments and explanations stronger, clearer, and more precise. This systematic approach to the development of math language can be broken down into the following four categories of support:
- Vocabulary: Units and lessons start by surfacing students’ language for new concepts, then building connections between their language and the new vocabulary for that unit.
- Language goals: Language goals attend to the mathematics students are learning, and are written through the lens of one or more of four language modalities: reading, writing, speaking, and listening.
- Math Language Routines: Math Language Routines are used within lessons to highlight student-developed language and ideas, cultivate conversation, support mathematical sense-making, and promote meta-cognition.
- Multilingual/English learner supports: Supports for multilingual/English learners (ML/ELs) are called out at intentional points within each lesson.
K-5 sample materials
Click the links in the drop-down sections below to explore sample materials from each grade. For a full program review, please login to the digital platform or request physical samples.
For helpful navigation tips and more program information, download the Amplify Desmos Math Program Guide.
You can also watch a product expert walk through a lesson and the available program components.
Teacher Edition
Planning and instructional guidance is visual, organized, and easy-to-follow. To help you preview the program, we have included samples from a complete sub-unit on this site: Unit 2, Sub-Unit 2: Counting and Comparing Images.
Student Edition
Motivate students with mathematics that is both rigorous and delightful. To help you preview the program, we have included samples from a complete sub-unit on this site: Unit 2, Sub-Unit 2: Counting and Comparing Images.
Ancillary sampler
Included in the ancillary sampler are examples from the program Assessment Resources, Intervention and Extension Resources, Centers Resources, Additional Practice, and Math Language Development Resources.
Featured digital lesson: Forest Friends
In this lesson, students apply their understanding of how to compare groups of images as they determine which group has more or fewer and then compare their strategies by guiding a bear through a path that has more mushrooms than the other.
Skills Unit 2 Teacher Guide
Planning and instructional guidance is visual, organized, and easy-to-follow. To help you preview the program, we have included samples from a complete sub-unit on this site: Unit 1, Sub-Unit 1: Adding and Subtracting Within 10.
Student Edition
Motivate students with mathematics that is both rigorous and delightful. To help you preview the program, we have included samples from a complete sub-unit on this site: Unit 1, Sub-Unit 1: Adding and Subtracting Within 10.
Ancillary sampler
Included in the ancillary sampler are examples from the program Assessment Resources, Intervention and Extension Resources, Centers Resources, Additional Practice, and Math Language Development Resources.
Featured digital lesson: Leaping Lily Pads!
In this lesson, students find differences when subtracting 1 and 2 from the same number by helping a frog reach a lily pad where it can eat a bug.
Teacher Edition
Planning and instructional guidance is visual, organized, and easy-to-follow. To help you review the program, we have included samples from a complete sub-unit on this site: Unit 1, Sub-Unit 1: Adding and Subtracting.
Student Edition
Motivate students with mathematics that is both rigorous and delightful. To help you preview the program, we have included samples from a complete sub-unit on this site: Unit 1, Sub-Unit 1: Adding and Subtracting.
Ancillary sampler
Included in the ancillary sampler are examples from the program Assessment Resources, Intervention and Extension Resources, Centers Resources, Additional Practice, and Math Language Development Resources.
Featured digital lesson: Ways to Make 10
Students continue to develop fluency by finding the number that makes 10 by helping a millipede reach its favorite food – a clump of leaves!
Teacher Edition
Planning and instructional guidance is visual, organized, and easy-to-follow. To help you review the program, we have included samples from a complete sub-unit on this site: Unit 1, Sub-Unit 3: Data on Scaled Graphs.
Student Edition
Motivate students with mathematics that is both rigorous and delightful. To help you preview the program, we have included samples from a complete sub-unit on this site: Unit 1, Sub-Unit 3: Data on Scaled Graphs.
Ancillary sampler
Included in the ancillary sampler are examples from the program Assessment Resources, Intervention and Extension Resources, Centers Resources, Additional Practice, and Math Language Development Resources.
Featured digital lesson: Puppy Pile
Students compare data represented on bar graphs with different scales by using animal stickers to create scaled bar graphs.
Teacher Edition
Planning and instructional guidance is visual, organized, and easy-to-follow. To help you review the program, we have included samples from a complete sub-unit on this site: Unit 1, Sub-Unit 2: Using Factors and Multiples.
Student Edition
Motivate students with mathematics that is both rigorous and delightful. To help you preview the program, we have included samples from a complete sub-unit on this site: Unit 1, Sub-Unit 2: Using Factors and Multiples.
Ancillary sampler
Included in the ancillary sampler are examples from the program Assessment Resources, Intervention and Extension Resources, Centers Resources, Additional Practice, and Math Language Development Resources.
Featured digital lesson: Hamster Homes
Students choose tube lengths to connect to platform heights for hamster homes, identifying possible heights using what they know about multiples.
Teacher Edition
Planning and instructional guidance is visual, organized, and easy-to-follow. To help you review the program, we have included samples from a complete sub-unit on this site: Unit 1, Sub-Unit 3: Volume of Solid Figures.
Student Edition
Motivate students with mathematics that is both rigorous and delightful. To help you preview the program, we have included samples from a complete sub-unit on this site: Unit 1, Sub-Unit 3: Volume of Solid Figures.
Ancillary sampler
Included in the ancillary sampler are examples from the program Assessment Resources, Intervention and Extension Resources, Centers Resources, Additional Practice, and Math Language Development Resources.
Featured digital lesson: Figures Made of Prisms
Students decompose a figure into rectangular prisms and determine the volume of the figure by adding the volumes of the individual prisms.
6-A1 sample materials
Click the links in the drop-down sections below to explore sample materials from each grade. For a full program review, please login to the digital platform or request physical samples.
For helpful navigation tips and more program information, download the Amplify Desmos Math Program Guide.
You can also watch a product expert walk through a lesson and the available program components.
Teacher Edition
Planning and instructional guidance is visual, organized, and easy-to-follow. To help you preview the program, we have included samples from a complete sub-unit on this site: Unit 6, Sub-Unit 1: Solving Equations.
Student Edition
Motivate students with mathematics that is both rigorous and delightful. To help you preview the program, we have included samples from a complete sub-unit on this site: Unit 6, Sub-Unit 1: Solving Equations.
Ancillary sampler
Included in the ancillary sampler are examples from the program Assessment Resources, Intervention and Extension Resources, Additional Practice, and Math Language Development Resources.
Featured digital lesson: Weight for It
Students use equations and tape diagrams to represent seesaw situations and to determine unknown animal weights, helping them make connections between diagrams that represent equations of the form `x+p=q` or `px=q`.
Teacher Edition
Planning and instructional guidance is visual, organized, and easy-to-follow. To help you preview the program, we have included samples from a complete sub-unit on this site: Unit 6, Sub-Unit 3: Inequalities.
Student Edition
Motivate students with mathematics that is both rigorous and delightful. To help you preview the program, we have included samples from a complete sub-unit on this site: Unit 6, Sub-Unit 3: Inequalities.
Ancillary sampler
Included in the ancillary sampler are examples from the program Assessment Resources, Intervention and Extension Resources, Additional Practice, and Math Language Development Resources.
Featured digital lesson: Shira the Sheep
Students solve inequalities with positive and negative coefficients to solve a variety of challenges featuring a fictional sheep who eats grass according to an inequality.
Teacher Edition
Planning and instructional guidance is visual, organized, and easy-to-follow. To help you preview the program, we have included samples from a complete sub-unit on this site: Unit 6, Sub-Unit 2: Analyzing Numerical Data.
Student Edition
Motivate students with mathematics that is both rigorous and delightful. To help you preview the program, we have included samples from a complete sub-unit on this site: Unit 6, Sub-Unit 2: Analyzing Numerical Data.
Ancillary sampler
Included in the ancillary sampler are examples from the program Assessment Resources, Intervention and Extension Resources, Additional Practice, and Math Language Development Resources.
Featured digital lesson: Robots
Students connect points on a scatter plot with individuals in a population and rows of data in a table. The analysis of scatter plots continues with data about the eye distances and heights of robots.
Teacher Edition
Planning and instructional guidance is visual, organized, and easy-to-follow. To help you preview the program, we have included samples from two complete sub-units on this site: Unit 2, Sub-Units 1–2: One-Variable Equations and Multi-Variable Equations.
Student Edition
Motivate students with mathematics that is both rigorous and delightful. To help you preview the program, we have included samples from two complete sub-units on this site: Unit 2, Sub-Units 1–2: One-Variable Equations and Multi-Variable Equations.
Ancillary sampler
Included in the ancillary sampler are examples from the program Assessment Resources, Intervention and Extension Resources, Additional Practice, and Math Language Development Resources.
Featured digital lesson: Shelley the Snail
Students represent the solutions of a situation using a table, a graph, and multiple forms of an equation to identify multiple combinations of blocks that can help Shelley the Snail cross a gap.
How problem-based learning can transform the math classroom
With test scores and student engagement on the decline, it’s clear that traditional teaching methods aren’t meeting the needs of all of today’s math learners.
One solution that’s gaining momentum is problem-based learning. By focusing on real-world problems and structured approaches, this approach develops critical thinking, reasoning, and application—skills that are essential for math success.
But making this shift isn’t easy. For math teachers and educators, it requires careful planning, a clear strategy, and community commitment.
That’s why we’re here to help.
The decline in test scores and engagement
The latest National Assessment of Educational Progress (NAEP) results show a sharp decline in math proficiency across grade levels. Only 26% of eighth graders performed at or above the NAEP Proficient level in 2022. These results represent the largest score declines in NAEP mathematics at grades 4 and 8 since initial assessments in 1990. The pandemic didn’t help, but it’s not the only factor.
This downward trend is compounded by a sense of disengagement. According to YouthTruth’s report Making Sense of Learning Math: Insights from the Student Experience, only half of students feel that what they’re learning in math connects to the real world. Recent survey data also shows that less than half of U.S. students feel that they “often” or “always” work on interesting problems in math class.
When math feels irrelevant or intimidating, students disengage—and the learning gaps that follow can be difficult to close.
An opportunity to grow
But the data also includes opportunities. According to NAEP research, more than 70% of students report that they enjoy activities that challenge their thinking and thinking about problems in new ways.
Problem-based learning helps give those students what they want.
And in a world that relies increasingly on data, analysis, and innovation, students need to learn not just how to follow steps and apply formulas, but how to think mathematically. In other words, problem-solving skills need to be part of student learning. This is particularly important in elementary and middle school math, where foundational concepts are built—and where students have the chance to forget their identities as “math people.”
That’s why working to infuse problem-based math learning into your district’s instruction can help reverse negative math and engagement trends.
What does problem-based learning in math look like?
Let’s go back and define this approach more fully. Research shows that math instruction is most effective when it encourages students—individually or grouped with peers—to grapple actively with math problems. When instruction gives students the opportunity and freedom to solve problems, rather than dictating solutions and then having them practice, students are more motivated.
For example, instead of memorizing the formula for calculating area and then practicing it in a series of disconnected problems, students might tackle a problem-solving challenge like:
How much paint is needed to cover our classroom walls?” Or they might work on a broader question such as: “How can we design a park, taking into account constraints like space, cost, and accessibility?
At its core, problem-based learning values mathematical thinking and reasoning. Rather than focusing on procedures and memorization, problem-based learning encourages students to:
- Explore open-ended problems.
- Ask questions and make connections.
- Develop strategies to solve problems collaboratively.
- Build curiosity and perseverance.
- Reflect on their reasoning and process.
In the problem-based learning classroom, students are positioned as active participants in their math experiences, building a deeper understanding of concepts as they work through challenges. This is particularly critical for ensuring students don’t just learn math, but understand why it works and how to apply it. These approaches can transform math classrooms into spaces where students build both foundational and real-world math skills—and a healthy dose of math confidence, too.
Critical factors in making the shift
Integrating problem-based learning into traditional math teaching can feel like (and is!) a big change—in lesson-planning, mindset, and more.
To make it work for administrators, teachers, and students alike, schools do best when they focus on a few critical factors. These include:
- Clear vision: Understand (and communicate) why the shift matters and what it looks like in action.
- Leadership buy-in: Gain commitment from school leaders and administrators.
- Teacher support: Offer professional development, resources, and ongoing guidance specific to math instruction.
- Structured approaches: Establish a well-defined plan for implementing problem-based learning in math classrooms effectively.
What problem-based learning can look like in the classroom
While problem-based learning offers proven benefits, it can be difficult to integrate into the classroom without a clear structure. Teachers need tools and strategies to guide students through the process and ensure that learning goals are met.
A structured approach to problem-based learning in math should include:
- Defining the problem: Present a clear, engaging math challenge connected to real-world scenarios.
- Student inquiry: Encourage exploration, discussion, and different solution paths.
- Collaboration: Support teamwork to share ideas and reasoning.
- Reflection: Allow students to evaluate their process, solutions, and learning.
This structured approach not only improves students’ conceptual understanding, but also aligns with Amplify’s research findings, which show that students who engage in active learning outperform their peers in more traditional settings.
By embracing problem-based learning in math classrooms, educators can:
- Boost student engagement and confidence.
- Improve student problem-solving and mathematical reasoning skills.
- Help reverse declines in math achievement over time.
- Empower students to see the value and relevance of math in academics and in their lives.
Ready to learn more?
If you’re ready to explore how your school can make the shift to problem-based learning in math, our new change management ebook is the perfect place to start. It offers practical guidance, real-world examples, and a deeper look at the strategies highlighted above.
Download the ebook now to discover actionable insights and strategies to help make problem-based learning come alive in your math classrooms.
Winter Wrap-Up 02: Mathematizing Children’s Literature
While we’re hard at work producing the exciting fifth season of Math Teacher Lounge: The Podcast, we’re continuing to share some of our favorite conversations from our first four seasons. This time around, we’re revisiting our popular episode that connected literacy and math!
In this episode, we sit down with Allison Hintz and Antony Smith, authors of Mathematizing Children’s Literature, to talk about what would happen if we were to approach children’s literature, and life, through a math lens–and how we can apply those same techniques to classroom teaching!
Explore more from Math Teacher Lounge by visiting our main page.
Bethany Lockhart Johnson (00:02):
Hi, I’m Bethany Lockhart Johnson.
Dan Meyer (00:04):
Hi, I’m Dan Meyer.
Bethany Lockhart Johnson (00:05):
And we are so excited for another episode of Math Teacher Lounge. And as you know, podcast format; you’re listening now. I think one beautiful thing about the podcast format is that it gives us a little bit more time to have these rich conversations. And I promise I won’t do it, but I could talk to our guests for hours, hours! Authors Allison Hintz and Tony Smith have just released Mathematizing Children’s Literature: Sparking Connections, Joy, and Wonder Through Read-Alouds and Discussion. And today we get to talk to the authors. Allison, Tony, welcome. Welcome to the lounge.
Allison Hintz (00:53):
Thank you. We’re so grateful to be here.
Bethany Lockhart Johnson (00:55):
We’re so excited to have you here. And I wanna say that my very first—was it my first math conference? Maybe it was my first math conference—up in Seattle, the CGI conference, and I’m all like, you know, wide-eyed and just like, “Can this be a place for me, this math community?” Re-envisioning my relationship with math and thinking about myself as a math teacher, what? And I went to your session on mathematizing children’s literature, and I was just so fired up. I was so wowed by your ideas, your energy, and your passion for students’ thinking. And I feel like as I read this book, I felt like I was hanging out with you. Like you were just so encouraging all the way through. Of educators, of other folks working with young people, and really guiding us how to listen with joy and with an open curious mind.
Dan Meyer (02:03):
Yeah. I would love to hear a bit about the genesis of this book for you folks. Like, I’m coming at this from a secondary educator lens. I’ve got small kids, so that’s also part of my interest here. But I love any book, any idea that seeks to merge what seems like two disparate worlds. Like it’s often the case that we feel like, well, there’s approaches for ELA and approaches for math, and they’re kind of separate disciplines. And these poor elementary teachers have to learn all of them and be experts at all of them. And here you both come along and say, “Hey, what if they are the same kind of technique?” Can you just speak to how this came about?
Allison Hintz (02:38):
Definitely. Tony, do you wanna take a try? Do you want me to start us off?
Antony Smith (02:42):
I can start. We oftentimes present and talk together and so we kinda switch back and forth. So that’s just how we are. So probably about eight or nine years ago, Allison and I, our offices were next to each other on our small campus. We’re both professors and we just happened to have a few children’s books that we looked at together and we were just thumbing through the pages. We really liked children’s literature. And we noticed that I would stop at certain points wondering about character motive or plot or sequence of events or language use. And Allison would stop at very different points in the book and notice number and concepts or something about mathematics. And that’s when we started to wonder, what would it be like if we were sharing a children’s book with a group of children and we put our ideas together? Where would we stop? What would we talk about? What would we ask children about in terms of their thinking and what they notice?
Allison Hintz (03:42):
And so we started playing with these questions that we had and started approaching stories with multiple lenses to see what kinds of things would children notice and what kinds of things might they say. And we were also on our own journey in trying to understand how to plan for and facilitate lively discussions and classrooms that surface really complex mathematics. And it felt like stories were a place where that might be a fruitful context for hearing children’s thinking. We’ve worked with a lot of teachers and students in our region. We live in the Seattle area and we’ve applied for some funding over time that’s really helped us be in a lot of community-based organizations and educational contexts and libraries and pediatricians’ offices and classrooms, various classrooms, and see what’s interesting about this and what might teachers and children do with stories that would surface complex mathematics to think about together.
Antony Smith (04:41):
Over time, we came to the realization that if we wanted to hear children’s ideas, we had to stop bombarding them with questions. <laugh> Yeah. And at first it made it worse that we were asking them math and literacy questions at the same time. And so we realized that what we needed to do was to back off and to ask children what they noticed and wondered.
Bethany Lockhart Johnson (05:01):
Can you say more about that and how that kind of evolved into mathematizing children’s literature?
Antony Smith (05:07):
We did work with a number of very thoughtful, talented classroom teachers and children’s librarians in public library systems who were just so masterful at asking open-ended prompts and questions, rather than kind of like the de facto reading quiz, that a read-aloud can become, which I’ve always disliked as a literacy educator. And we realized in our observing these read-alouds or interactive read-alouds or shared reading experiences that given the opportunity in the space and an adult who was actually listening, that children came up with all of the ideas we would have asked them about and more. So we didn’t have to be bombarding them with questions. They were already much more thoughtful than what would’ve been sufficient to answer our questions.
Allison Hintz (05:58):
And much like mathematics, it was really an iterative process. You know, we had some clunky read-aloud discussions where we were trying to accomplish so much and toggling multiple chart papers and different colored pens and all sorts of “how do we capture these ideas” and “do we separate ’em? do we keep ’em together?” And so it’s really been over time that with partners, we’ve learned these ways of having multiple reads of the same story that allow us to hear what children notice and wonder, and then to delve more deeply into their questions and their ideas through multiple reads where we might spotlight literary ideas that they notice; we might spotlight mathematical ideas that they notice. We might make purposeful integrations between those. But we found it to be most productive—and Kristin Gray really help us think about this—to have an open Notice and Wonder, get everything out much like an open-strategy share. We welcome here, record all the ideas, and it goes all over everywhere. You know, it can be a really not math-y noticing! And those are amazing! So there’s a lot of, um, yes, there is a ladybug on this page! The grandma is wearing green triangle earrings! Oh, your grandma wears green earrings! I mean, it all comes out.
Bethany Lockhart Johnson (07:27):
Wait, have you been in my classroom? ‘Cause that’s exactly— <laugh>
Allison Hintz (07:29):
<laugh> And then, you know, we think of it a lot like if math teachers might use the 5 Practices for selecting and sequencing, or if you might move from an open-strategy share to a targeted share, how can we get out all the questions that children are asking and then step back from them, take some time to really think about what they’re telling us they’re curious about, and plan some purposeful, intentional subsequent discussions that can delve more deeply into their ideas.
Dan Meyer (08:02):
I’d love to go into that a little bit more if that’s all right. Um, I’m gonna speak from someone who doesn’t have an elementary background and I’m gonna voice some worries that I had, some anxiety. One anxiety I have like in a classroom or a curriculum is when there’s no room for student ideas. Right? When it’s like, oh, there’s just room for the curriculum author or the teacher here. That is a sadness. But I when I see an instructional environment like you’re describing here, where there is openness to all kinds of different student ideas, of different levels of formality, from different kinds of cultural fonts of knowledge or wherever, I also get a little bit nervous because that, like, increases the risk that a student might come to understand that “my ideas are not good enough,” whereas in the class with no room for their ideas from their home or their language or their hobbies, like, they’re not gonna internalize the message that, “that wasn’t good enough.” And so I’m really curious as you move from the open Notice and Wonder where kids share all of themselves with you, and then you move to a targeted focus on some sort of disciplinary objective, how do you navigate that tension and help students feel like their contributions are valuable, even though we aren’t taking them up per se?
Allison Hintz (09:18):
That’s such an important question. I mean, I think we’ve grappled with this broadly in math education. I think any time we’re thinking about which ideas we choose to take up to pursue to consider, we have a responsibility to think carefully about whose ideas are being taken up and heard and considered. And so one of the tensions I hear you naming, I think, Dan, is when we engage in lively discussion where children’s thinking’s at the center, how do we make sure to upend and interrupt kinda status norms that run the risk of being deepened? Um, and I think by paying attention to whose ideas are taken up as much as which ideas are taken up, and what’s the mathematics we wanna explore is one tension. Um, another tension I might hear you naming is, you know, the complications that teachers face with time and pressure and coverage, and which mathematics ends up getting worked on. And, um, you know, it’s something we’ve really had to struggle with in mathematics education, where we move to more discussion-oriented classrooms that are really centered in sense-making to know that it takes a lot of time to do this thoughtful, thoughtful work. Um, does that begin to get at some of the tensions you’re raising? Is there, is there more you’re thinking about?
Dan Meyer (10:53):
I think it’s really helpful that you kind of broadened the scope of the question beyond your book to “this is an issue that we are, you know, really challenged by and focused on broadly in math education.” And, um, I appreciate you bringing the element in of whose idea—not just which idea is taken up, but whose idea is taken up—is an opportunity where, let’s say, multiple people raise an idea that is towards an objective the teacher has, they have the opportunity to disrupt certain kinds of status, like ideas about status, in that moment. From your perspective, like, are there techniques to say, I don’t know, parking-lot certain kinds of questions and say like, “Hey, like these are awesome”? I don’t know. I just know that I see kids at like ninth grade. They are very reticent, often. They’ve internalized totally this sense of like, “I’m not gonna just, like, share about the pants the grandma’s wearing, you know; that will not be received well.” And so I’m just kinda wondering how that happens and like, what are the ways we can disrupt that? That process?
Antony Smith (11:54):
So thinking about that, Dan, from the teacher’s perspective, in those kinds of scenarios where you wanna honor each child’s contribution, a couple of things that come to mind: One is that by, you know, initially by modeling what I as a teacher, something that I notice or wonder about, helps kind of set the expectation for what kind of response would be encouraged. And it’s broad, but it gives an example. And then also we really try to record or to chart all of the ideas that are shared so that we can revisit and honor those together. And then either later or on another day, if we choose one or two of those to explore in some way within a more focused read, then another thing that we do is have the idea investigation afterward that continues that thought, but goes back to being as open-ended as possible, so that those students or children who maybe didn’t have their idea as the one that was focused on by the group could go back to that or explore some other idea of their own, so that the idea investigation isn’t a lockstep extension activity, which is why we don’t call it that. So they could again bring in their own perspective. But I have to say from the teacher’s point of view, there is that moment of potential panic <laugh> because there is that power transfer when you’re asking children to help steer where this is going. And if you really mean it, you have to let them steer a little bit. And that can be terrifying. And, um, I always think of one teacher, Ashley, we worked with who read an adorable book, Stack the Cats, by Susie Ghahremani. And in that book, there’s a point where there are eight cats and they’re kind of trying to be a tower of cats and they fall and they’re sort of in the air on that page. And she asked her first graders—she stopped, and she asked, “How, do you think, how will the cats land?” And for about a minute and a half, the entire <laugh> class, was silent. They had their little papers; they had chart paper; they had clipboards; they had everything they needed. But that unusual phenomenon of a group of six- and seven-year-olds actually just sitting and thinking and not being peppered with activities was really stressful, but amazing. And then, after about the 90 seconds, they started out into their exploration of how the eight cats might land. They just needed a minute to think. And it’s so rare that we’re able to let children have that.
Allison Hintz (14:40):
In that same moment, Ashley, who’s a learning partner to us, she turned to us kind of quietly, like, “Should I pose a different question?” And <laugh>, we’re like, “No, let’s stick with it. Let’s see what happens.” So I think it creates this space too, this thinking culture, right? And this culture of “what does that mean to really pose a rich task?That’s open-ended, where there’s multiple access points?” Those eight cats could land in so many different ways. And there was broad access, there was a wide range of all the cats landing, and one’s on their feet, ’cause cats always land on their feet <laugh>, and there was every combination. And so, um, I think what’s really interesting—and to me, this brings back to your wonder, Dan—is, you know, “What’s the risk in openness?” And there’s always risk in openness. Um, it’s scary as a teacher, right? If I’m not the authority of knowledge and I don’t have control over where we’re gonna go, it might get into places that I didn’t anticipate. Or I don’t really feel as solid in the math as I want to. Or I don’t know what it sounds like to stick with silence and wait time, to know if my students are really in productive struggle or if that question was a flop. And so, um, I think this is some practice space for young mathematicians and teachers of mathematics, and just teachers, to explore with that openness and kind of the risk of the openness required for complex thinking to emerge.
Bethany Lockhart Johnson (16:12):
You know, it feels like the way you’re both describing this, it really is a culture shift, right? I kept feeling like I was given permission to be a beginner as I read this book. Like I was really…I loved how you said, I believe it was you, Allison, when you were in the class, you had a couple index card that you kept on your clipboard and that as you walked around, you were like, “Hey, if I don’t know what to ask, I ask one of these questions.” You know? And just this idea that, that, like Dan was saying, there is that loss of control, but that’s also a way to create this culture where students ideas are valued and we are allowing students to really generate the questions, which I thought was such an important idea to explore.
Allison Hintz (17:00):
We started this work long ago, super-excited about math-y books. And we saw a lot of potential in them and we still do. But the limitation we saw is that math-y books, they, they put forth a certain mathematics to be curious about. In some ways they tell you what mathematics to think about. So we started asking ourselves what would happen if we considered any story a chance to engage as mathematical sense-makers. And we started playing with non-math-y books and we got to a place where we could consider every story an opportunity to engage in mathematical thinking. And so we started noticing things over times, oh, these books tend to be really math-y. We call those text-dependent. We’d have to pay attention to the mathematics to understand the story. Whereas this pile of stories, these, they’re not overtly math-y. You could really enjoy the story and not pay attention to mathematics and have an amazing conversation. But what would happen if we thought of about this story as mathematical sense-makers and how might it deepen our understanding of the story? And then this other teetering pile of books, these are books where, you know, children didn’t tend to engage as overtly as mathematicians in it, but there’s opportunities in this story to go back to something—to a moment, to an illustration, to a comment—and think as mathematicians. And those were more about illustration exploring. And so, as we notice these different kinds of books, we really broaden what we thought about. And I think one of the things we really wanna think about in community through this book is what happens if we approach any story, every story, as mathematical sense-makers, because stories are alive in children’s lives, in homes and communities and in schools. And it’s a broad opportunity that we wanna take up. I was thinking, as I stay in this strait for just a moment about book selection, before we move into that process, um, Bethany in a previous MTL, you talked about representation.
Bethany Lockhart Johnson (19:12):
Mm, yeah.
Allison Hintz (19:14):
And do you remember when you shared the image of hair braiding?
Bethany Lockhart Johnson (19:19):
Yes. Vividly, yes. <laugh>.
Allison Hintz (19:22):
Yeah. And can you say just what that meant to you? What that….
Bethany Lockhart Johnson (19:27):
Yeah. Well, it was from a conference; Sunil Singh had used it and was talking about the artistry in mathematics and beauty in hair braiding. And, um, particularly, he was showing this particular image of this Black woman with her hair braided in profile and looking at the angles and the symmetry. And I shared that, you know, I spent so many hours in the beauty shop with my aunties and my mom and my grandma and continue to, to this day, that it just, it struck me immediately as familiar. And it struck me immediately as seeing an image that was reflective of my lived reality, projected as valuable and worthwhile for consideration in the world of mathematics. Which is not what I felt as a student of mathematics as a young adult or child. So it was this beautiful moment of, for me, the power of when we see images and we allow opportunities for re-envisioning what may be a common practice for that student, or may be something that they see every day.
Allison Hintz (20:44):
And in that same way, that image that was put up, we wanna think really carefully about representation in the stories that we select. And when we think of stories as mirrors or windows, we really wanna be mindful in story selection of whose stories are told and whose stories are heard. And when you said that you would sit down to listen to a story and you felt at ease or that you saw an image and you saw yourself that can be and should be something we really think carefully about when we select the stories that we select.
Dan Meyer (21:21):
It’s a wider path for representation of different kinds of people in literature, because people’s stories seem so much more present and towards the surface of their lives, versus, say, the abstractions and numbers and shapes in mathematics. It feels like more of a struggle to find ways to show people, hey, like you’re here, this, this place belongs to you. So in all these reasons, I think it’s really great you folks are using literature, which has this history of humanities, literally humanities, as a vehicle for mathematics. That seems pretty special here.
Antony Smith (21:56):
We both go to libraries and bookstores and look through books as often as we can, but also our partner, a children’s librarian, Mie-Mie Wu, helped us go through—when we would meet, she would bring three or four hundred books at a time.
Bethany Lockhart Johnson (22:13):
When you described her wheeling in the cart, oh, I wish I been in that room! <Laugh>
Antony Smith (22:18):
And the cart was, you know, probably three or four times bigger than she was sometimes. And we would go through hundreds of books and look at them and listen to her thoughts as a skilled librarian sharing with families, diverse families, and what catches the attention of a three-year-old sitting with her grandfather. And that was really a valuable, helpful experience. And it’s a partnership that continues. So in Last Stop on Market Street—and this is in the book; we talk about this, this children’s book quite a bit—in this story, CJ with his Nana, his grandmother, are riding the bus to the last stop on Market Street in San Francisco, to go, as we will find out, to help serve in a soup kitchen to help the community. And the teacher, Susan Hadreas, had the children record their ideas. She charted them in an open Notice and Wonder read. And one of the ideas that a young boy noticed was that CJ on the bus…a man with a guitar starts playing the guitar on the bus and CJ closes his eyes and it says CJ’s chest grew full. And he was lost in the sound and the sound gave him the feeling of magic. So this boy said, “I wonder, what does that feel like if you’re feeling the magic? What’s that?” And that was one of many ideas in the open Notice and Wonder, and Allison will talk about the math lens read, but first Susan went back and read with them. She had that idea, she circled it on the chart paper, and another day that week, she said, let’s go back and visit this story we really liked. And remember, we wondered what feeling the magic was like. Let’s go back through and let’s keep track of all the feelings and emotions that CJ had across the journey to the soup kitchen in this book. And so they did another read of the story; they were very familiar with it, of course, but they noticed new things and they also, every few pages, stopped and she helped chart all of the emotions that CJ experienced from envy to excitement to sadness. There’s a huge range in this book. And it was fascinating.
Allison Hintz (24:36):
I think one of the things that the children noticed was that CJ’s feelings were shaped by community. And that he shaped and shaped…he was shaped by and helped shape his community. And so the ways that he felt across the story were impacted by the other characters that he comes across. The guitar man on the bus. The bus driver who can pull a coin out from behind someone’s ear. The lady with the butterflies in the jar. Nana helping him to see the rainbow. And the students started, you know, being curious about that. How do we shape and how are we shaped by community? What communities are we a part of? This class is one community. I’m in many communities across my life. And they started to quantify the number of people in the story. So Mrs. Hedreas went back for a math lens read, and she said, let’s just keep track of and pay attention to how many people are in CJ’s life in this day. Because I can hear you starting to think about quantity. This class at the same time in other areas of the day had been working on counting collections, how to keep track, so they got out their tools. Some people pulled out ten frames, some people pulled out clipboards. They had a wide range of things they could use to help them keep track. They developed their own strategy, keep track however you want. She did a quicker read through it, flipping the pages, and then they get into these debates: <laugh> “We already counted that person!” “But they took their hat off and put it down to collect money!
Antony Smith (26:10):
“What about the dog?”
Allison Hintz (26:11):
“That’s the same person!” “Yeah, there’s a dog pound in his community!” <laugh> “Do animals count in our community?”
Bethany Lockhart Johnson (26:17):
I love it!
Allison Hintz (26:17):
“Yes, they count!” Uh, and so we went through and quantified and there was really this understanding as you saw these people throughout the story that communities can be of different sizes, but community has impact. And you have responsibility in your community to show up and to lean in and to know that bringing your full, authentic, vulnerable self, you shape people and they shape you. And what communities are people a part of. And it turned into this really interesting discussion about quantity and helped us think more about quantity and community. I think a really important moment for us and for that class was the transition from being people who almost did mathematics to a story, like counted things on a page, um, count acorns on a page in an autumn book, to being mathematicians who thought within the story.
Antony Smith (27:17):
And then two idea investigations that came from that —not at the same time, of course, but with the same group of children—one was they identified an emotion of their own and wrote and drew about that. And also, who helped them address or get out of or acknowledge that emotion. And then the other idea investigation was that all of the children drew or kind of mapped out a community that they were part of. Whether it was their neighborhood or their classroom or their soccer team or whatever it was. And so then those investigations strengthened the connections of those concepts to the lives of those children.
Bethany Lockhart Johnson (28:05):
Well, I, actually wanted to ask you about idea investigations. Because I feel like that was such an important invitation in your book. And the way I understood the idea investigation is you’re really paying attention to what’s coming up in your other reads. Right? And then these are opportunities to extend the thinking, or like you said, to extend a particular aspect: What’s your community? Can we map your community? Or what’s a particular emotion? And it was in such contrast to what I think I have probably done in my classroom more than once, which was like, “Oh, we read this story about seals. So now my story problem is gonna be about seals, right? <laugh> Like in the story, you know, Jojo, the seal had five balls. <laugh> So if Jojo still had five balls and two of them bounced away…” You know, or whatever. Right? But that’s not what an idea investigation is. Right?
Allison Hintz (29:03):
Yeah. I think this is where we also had some stumbles and can totally relate to what you’re saying as previous classroom teachers as well. We have come to a place where we are pretty in favor of a super open-ended idea investigation that takes up the things that have surfaced in the multiple reads and making sure it’s a rich task with many, many ways children can engage with that. There’s many, many, many right answers or ways to engage. Less is more there. So we moved way away from, like, even a worksheet that might have an idea from it to blank paper and math tools and places to get into some productive struggle around some of the complex things that were raised.
Antony Smith (29:59):
A challenge with worksheets is that they put a frame around children’s ideas. So either there are only three lines to write on, or there’s only a small box to draw in. Whereas a blank page really opens up the possibility. Um, and so—is it Ann Jonas who wrote Splash!? sorry, I don’t have it in front of me—the book Splash!, about animals that end up in and out of the pond, including a cat that is not happy about ending up in the pond, an idea investigation after that for very young children was, with the list of the different creatures displayed at the front of the room: On blank paper, hey, draw your own pond and decide how many of which and each type of animal you want in your pond and then write about it. Just on blank paper. And so that allowed some children to draw, like, three giant goldfish. But other children drew 17 frogs and three cats. And, and just, it lets children follow—
Bethany Lockhart Johnson (31:02):
It was theirs, right? It was theirs.
Antony Smith (31:04):
Their idea. <laugh> And that comes partly from, I think, as Allison mentioned, we both were classroom teachers before moving into academia. And I remember giving children worksheets, particularly math worksheets, where they weren’t necessarily bad, but right at the bottom, it says like, explain your strategy. And it gives two lines.
Bethany Lockhart Johnson (31:23):
Right! <laugh>
Antony Smith (31:25):
The only thing a seven-year-old can write there is “I thought.” Or “I solved it.” <laugh> And that’s not where we need to go.
Dan Meyer (31:34):
Yeah. If I could just ask the indulgence of the primary crowd here, like, I’m trying to make sense of all this. And I just wanna like, offer my perspective. My summary statement of what’s going on here. I’m trying to—I love how you both came here—
Bethany Lockhart Johnson (31:45):
<laughs> How ya doin’, Dan? How ya doin’?
Dan Meyer (31:47):
<laughs> I’m, ah, A, I’m loving this a lot. Um, B, I came in here loving how you folks are broadening the work of primary education to kind of find commonalities between these sometimes seemingly disparate kinds of teaching in ELA and math. Love that, I wanna say. But I think you folks are describing, with all these teachers you observed and your own work, is the work of attaching meaning to what students might not realize yet has meaning. Or they might think it only has one kind of meaning. But you, the teacher, with their knowledge, realizes that there are many more dimensions of meaning that can be attached to those thoughts. And I’m hearing that from you folks, when you describe A, what math is and the power of a teacher to name a thing as mathematical. Like, “Oh, you didn’t think math was that, but math is noticing; math is wondering; math is asking questions,” for one. But also this work you’re describing of how, like, first the task has to invite lots of student thoughts and then to say like, “Oh, I see that there’s a similarity to these two.” And to raise those up for a conversation or to ask a question like to extend one person’s, one student’s question a little bit more. But it’s always…I’m just hearing you folks attaching more meaning than the student might have originally thought. I appreciate the conversation. That’s really interesting.
Bethany Lockhart Johnson (33:03):
Well, and now that the book is out, I think it’s gonna keep evolving, right? Now that it’s gonna be in the hands of teachers and librarians and educators and caregivers, it’s exciting to see kind of where it goes next. Which actually brings us to our MTL challenge. Dan Meyer, do you wanna share?
Dan Meyer (33:22):
Math Teacher Lounge, we have a challenge for the folks who listen and we’d love for them to hop into the Facebook group Math Teacher Lounge, or hit us up on Twitter at @MTLShow and just, like, kind of exercise beyond listening, exercise the ideas you folks are talking about, some kind of a challenge that can help us dive deeper into your ideas. So what would you folks suggest for our crowd, for our listeners?
Allison Hintz (33:42):
I would love to invite people to playfully experiment with a favorite story, with a story that’s new to you. I would love to invite listeners to sit with a story maybe on your own, and just ask yourself as a mathematician: What do you notice and wonder in this story? Don’t feel any pressure. Maybe sit with a child or some children and listen to what they notice and wonder. Like, really listen! Don’t ask questions! But hear their questions and place children at the center and consider multiple reads. Consider continuing to pursue their questions. And we have a planning template that might support people in kind of sketching out some ideas if you’re open to playing with that too.
Bethany Lockhart Johnson (34:34):
And we will post—
Dan Meyer (34:36):
That’s awesome.
Bethany Lockhart Johnson (34:36):
—a link for that planning template in our Facebook group and on Twitter as well. So thank you so much for that resource, because I think it’ll definitely help. It could help you, like you said, it could help you kind of organize your thoughts or help you think about this work in a new way. So thank you for that resource and thank you for the amazing resource that is Mathematizing Children’s Literature. I am so excited to continue to engage with you both and with listeners as they dive into this book. If folks want to engage with you more, where can they find you? How can they reach you?
Allison Hintz (35:12):
Well, we’re on Twitter.
Bethany Lockhart Johnson (35:14):
Great.
Dan Meyer (35:15):
What’s your home address? <laugh>
Bethany Lockhart Johnson (35:24):
Wait, let me try that again. <laugh> ‘Cause it does sound like I’m like, <fake ominous voice> “Where can they find you?”
Allison Hintz (35:29):
4-2-5…. <laughs>
Antony Smith (35:32):
At the bookstore!
Bethany Lockhart Johnson (35:34):
Y’all, if folks want to continue this conversation or share these ideas or the math challenge, how can they tag you? How can they, they reach you on the World Wide Web, besides the Math Teacher Lounge Facebook group?
Antony Smith (35:50):
Yeah. Well, we are both on Twitter, and we’ve been trying to promote the hashtag #MathematizingChildrensLiterature. It’s very long, but once you type it once, your phone or computer…
Bethany Lockhart Johnson (36:01):
Easy. Yeah, those click, right? Is that what it is now?
Antony Smith (36:03):
<laugh> The other is that we do for our project, we have an Instagram account that is @MathematizeChildren’sLiterature.
Allison Hintz (36:11):
We care really deeply about hearing from people. You know, we think our ideas are constantly evolving and that there’s such exciting room to grow. And we just felt compelled to share what we were learning now so that together we could learn and build vibrant experiences for young children and teachers and families through stories. So we want to hear from people! We wanna learn about stories that are important in your lives and what children say, and grow these ideas together.
Bethany Lockhart Johnson (36:42):
And credit to Dan, you told me you went and ordered a bunch of the books they have on the suggested read list.
Dan Meyer (36:48):
Oh my gosh.
Bethany Lockhart Johnson (36:49):
You read ’em to your son.
Dan Meyer (36:50):
I got such a side-eye from my significant others around here for what I dropped on Amazon in one night! <laugh> Uh, all these books I didn’t have. Some of them I did. We are not fully illiterate around here! We do love the written word at the Meyer household! But there were a bunch that that I grabbed. I’m morseling them out day by day.
Bethany Lockhart Johnson (37:09):
Wait, at bedtime I read my one-year-old One Is a Snail, Ten Is a Crab. <laugh> And let me tell you, he had vigorous pointing and “Da? Da da da da?”
Allison Hintz (37:22):
<laugh> Aww, da da!
Bethany Lockhart Johnson (37:22):
So hey, we’re on the road. <laugh> <music> Deeply grateful, not only for your work and your beautiful book and your work, but also for the invitation to dive into the world of children’s literature in a way that many of us have not before. And it’s fun! Thank you, Tony. And thank you, Allison. And thanks for hanging out in the lounge.
Allison Hintz (37:48):
Thanks for having the lounge!
Antony Smith (37:49):
It’s been fun!
Allison Hintz (37:52):
Thank you both.
Stay connected!
Join our community and get new episodes every other Tuesday!
We’ll also share new and exciting free resources for your classroom every month.
Meet the guest
Allison B. Hintz: Dr. Hintz’s research and teaching are in the area of mathematics education. Her focus on mathematics came about during her years as a fifth grade teacher – it was alongside her students that she developed her own positive identity as a mathematician! Today she studies teaching and learning, specifically facilitating engaging discussion. Her research and teaching happen in partnership with educators and children in formal and informal settings and focuses on beliefs and practices that support all children in lively mathematics learning. She is a co-author, with Elham Kazemi, of Intentional Talk: How to Structure and Lead Productive Mathematical Discussions.
Twitter: @allisonhintz124
Antony T. Smith: Antony T. Smith is an associate professor of literacy education at the University of Washington, Bothell. He works alongside teachers to create engaging literacy-mathematics learning experiences through exploring and discussing children’s literature. He is committed to the concepts of motivation, engagement, challenge, and creativity in literacy teaching and learning.
Twitter: @smithant Instagram: mathematizechildrensliterature
About Math Teacher Lounge: The podcast
Math Teacher Lounge is a biweekly podcast created specifically for K–12 math educators. In each episode co-hosts Bethany Lockhart Johnson (@lockhartedu) and Dan Meyer (@ddmeyer) chat with guests, taking a deep dive into the math and educational topics you care about.
Join the Math Teacher Lounge Facebook group to continue the conversation, view exclusive content, interact with fellow educators, participate in giveaways, and more!
You might also like:
A Step-by-Step Guide to a High-Quality Curriculum Adoption
Welcome
We created this guide to help leaders like you navigate the complex process of adopting a high-quality curriculum.
Leading a curriculum adoption process involves coordinating groups of people, comparing programs, and championing your decision to ensure your community is on board.
On this site, you’ll find our recommendations along with downloadable articles and templates to help you with your review and decision-making process. Don’t go it alone. Let us help.
Tell us a little about your adoption to access the guide.
Contact information
All fields are required.
Program introduction
Professional learning
What will you find in the Professional Learning section?
Whether you’re launching into a new program or looking to strengthen your skills, Amplify’s professional learning sessions will support your needs.
- Register now to join new and upcoming learning sessions.
- On-demand sessions offer timely insights to support your mCLASS implementation.
- Webinar recordings from 2020-2021 or 2021-2022 ensure you don’t miss a thing.
Amplify is working in partnership with the Kindergarten Assessment Support (KAS) Initiative to provide virtual professional development trainings to teacher, specialists, and campus/district leader users of mCLASS Texas Kindergarten across the state of Texas. These trainings are funded by the KAS Grant and will be provided at no charge to participants. Please note that all content will be focused on kindergarten only.
You will find a list of sessions below that you can register for. Sessions will be updated on an ongoing basis. To register, educators can enter the Session ID number into the Region 4 ESC search bar (https://www.escweb.net/tx_esc_04/) to sign up for the session(s) and to secure a spot or type ‘mclass’ into the search bar; all virtual sessions are capped at 30 participants.
For more information about the KAS Initiative, please visit https://tea.texas.gov/academics/early-childhood-education/data-driven-instruction-best-practices.
View the on-demand sessions for below to gain timely insights to support your mCLASS implementation.
All mCLASS Texas Edition users will have access to free online modules. Contact your district for details about accessing these modules.
For those districts that want to support teachers in a more comprehensive approach we will work to ensure that the professional learning section supporting each mCLASS Texas Edition rollout meets each district’s unique needs. Here is a professional learning catalog to show the breadth and depth of what we offer.
Remote assessment
mCLASS Texas Edition can be administered in many ways, including remotely. This site will give guidance on the various ways to administer mCLASS Texas Edition to best support your students in any learning environment.
Watch the Remote Assessment Guidance Office Hours recording here.
Documents referenced during Office Hours are linked below.
Administrators, welcome to mCLASS Texas Edition!
Here you’ll find information about enrollment and licensing, technical requirements, professional learning resources, and more.
Onboarding: What to expect
Welcome to mCLASS Texas Edition! To help you know what’s coming next, we created the following visual that outlines the steps of the onboarding process. You can use it as a reference.
Enrollment and licensing
Amplify provides services to fit the different types of enrollment needs for various times of year:
- Self-Service Enrollment (SSE) is a batch enrollment tool that you can use to import large amounts of student, staff, and class information into the Amplify system at the beginning of the school year or any time you need to update your enrollment data.
- Auto Self-Service Enrollment (Auto SSE) is a service for automatically sending enrollment data from your computer to Amplify, which does not require intervention after you initiate the process, and which can be run at any time of year. You must have the ability to run scripts in order to use Auto SSE.
- Amplify also offers the Manual Enrollment tools on the Amplify Administration page, which you can use at any time of year to add or update enrollment information by entering the information directly into Amplify, rather than uploading spreadsheets.
Preparing your materials
Click here to access a list of the print materials included in each mCLASS Texas Edition kit.
Technology requirements and guidelines
To ensure that your hardware and network meet the minimum technical requirements for optimal performance and support of your digital curriculum products, please see Amplify’s customer requirements page.
To ensure access to mCLASS, add the URLs on this page to your corresponding district or school-level filters.
Teachers, welcome to mCLASS Texas Edition!
Here you’ll learn about the program, how to set up your device, and how to get help when using mCLASS Texas Edition.
Onboarding: What to expect
Logging in to mCLASS Home
mCLASS Home is where you access mCLASS reporting, instruction, and other helpful resources. Follow these steps to log in:
1. Navigate to mclass.amplify.com.
2. You will need your Amplify user name and password to log in. If you forget your password, you can follow the instructions below to generate a new one.
- Click “Forgot Password”
- Enter your Amplify username and your district or school email address. Click Send. Then follow the instructions in the email you receive to reset your password.
If you have not received an Amplify username and password, please contact your
school or district administrator.
Setting up your assessment device
Assessments are administered using the mCLASS app. The mCLASS app is installed by creating a shortcut from Chrome™ (Safari for iPads) on your device’s desktop or home screen. Click the link for your device for installation instructions:
iPad
Chromebook
Windows device
Note that you need your Amplify username and password to install the mCLASS app. If you have not received it, please contact your school or district administrator.
Dyslexia screening
mCLASS® Texas DIBELS® 8 and IDEL assess the updated skills required for dyslexia screening. We’ve got you covered!
Click here to learn more about the Texas Dyslexia handbook updates.
Looking for help?
Our technical and pedagogical support teams are available from 7 a.m. to 7 p.m. ET, Monday through Friday.
For your most urgent questions
- Use our live chat within your program
- Call our toll-free number: (800) 823-1969
For less urgent questions, send us an email!
- Technical support: help@amplify.com
- Pedagogical support: edsupport@amplify.com
Welcome to Amplify Science 6–8!
Amplify Science is an engaging core curriculum designed for three-dimensional, phenomena-based learning.
With Amplify Science, Oregon students don’t just passively learn about science concepts. Instead, they take on the role of scientists and engineers to actively investigate and figure out real-world phenomena. They do this through a blend of cohesive and compelling storylines, hands-on investigations, collaborative discussions, literacy-rich activities, and interactive digital tools.
Publisher presentation
The Lawrence Hall of Science
Developed by the science education experts at UC Berkeley’s Lawrence Hall of Science and the digital learning team at Amplify, our program features:
- A phenomena-based approach where students construct a complex understanding of each unit’s anchor phenomenon.
- A blend of cohesive storylines, hands-on investigations, rich discussions, literacy-rich activities, and digital tools.
- Carefully crafted units, chapters, lessons, and activities designed to deliver true 3-dimensional learning.
- An instructional design that supports all learners in accessing all standards.
Proven to work
Instructional model
The Amplify Science program is rooted in the proven, research-based pedagogy of Do, Talk, Read, Write, Visualize. Here’s how each element works:
Do
First-hand investigations are an important part of any science classroom, and Amplify Science has students getting hands-on in every unit—from building models of protein molecules to experimenting with electrical systems.
Talk
Student-to-student discourse and full-class discussions are an integral part of the program. Students are provided with numerous opportunities to engage in meaningful oral scientific argumentation, all while fostering a collaborative classroom environment.
Read
Students read scientific articles, focusing their reading activities on searching for evidence related to their investigation and, importantly, on asking and recording questions as they read through fascinating texts on 21st-century topics.
Write
Following real-world practices, students write scientific arguments based on evidence they’ve collected, making clear their reasoning about how a given piece of evidence connects to one of several claims.
Visualize
By manipulating digital simulations and using modeling tools to craft visualizations of their thinking— just as real scientists and engineers
do—students take their learning far beyond the confines of what they can physically see in the classroom in an exciting and authentic way.
Program structure
Our cyclical lesson design ensures students receive multiple exposures to concepts through a variety of modalities. As they progress through the lessons within a unit, students build and deepen their understanding, increasing their ability to develop and refine complex explanations of the unit’s phenomenon.
It’s this proven program structure and lesson design that enables Amplify Science to address 100% of the NGSS, and support students in mastering the Oregon Science Standards.
Unit types
While every unit delivers three-dimensional learning experiences and engages students in gathering evidence from a rich collection of sources, each unit also serves a unique instructional purpose.
In grades 6–8:
- One unit is a launch unit.
- Three units are core units.
- Two units are engineering internships.
Launch units are the first units taught in each year of Amplify Science. The goal of the Launch unit is to introduce students to norms, routines, and practices that will be built on throughout the year, including argumentation, active reading, and using the program’s technology. For example, rather than taking the time to explain the process of active reading in every unit in a given year, it is explained thoroughly in the Launch unit, thereby preparing students to read actively in all subsequent units.
Core units establish the context of the unit by introducing students to a real-world problem. As students move through lessons in a Core unit, they figure out the unit’s anchoring phenomenon, gain an understanding of the unit’s disciplinary core ideas and science and engineering practices, and make linkages across topics through the crosscutting concepts. Each Core unit culminates with a Science Seminar and final writing activity.
Engineering Internship units invite students to design solutions for real-world problems as interns for a fictional company called Futura. Students figure out how to help those in need, from tsunami victims in Sri Lanka to premature babies, through the application of engineering practices. In the process, they apply and deepen their learning from Core units.
Unit sequence
Our lessons follow a structure that is grounded in regular routines while still being flexible enough to allow for a variety of learning experiences.
In fact, our multi-modal instruction offers more opportunities for students to construct meaning, and practice and apply concepts than any other program. What’s more, our modular design means our units can be flexibly arranged to support your instructional goals.
Program components
Available digitally and in print, our unit-specific reference guides are chock full of helpful resources, including scientific background knowledge, planning information and resources, color-coded 3D Statements, detailed lesson plans, tips for delivering instruction, and differentiation strategies.
Hands-on learning is an essential part of Amplify Science, and is integrated into every unit. Students actively participate in science, playing the roles of scientists and engineers as they gather evidence, think critically, solve problems, and develop and defend claims about the world around them. Every unit includes hands-on investigations that are critical to achieving the unit’s learning goals.
More hands-on with Flextensions:
Hands-on Flextensions are additional, optional investigations that are included at logical points in the learning progression and give students an opportunity to dig deeper if time permits. These activities offer teachers flexibility to choose to dedicate more time to hands-on learning. Materials referenced in Hands-on Flextension activities will either be included in the unit kit or are easily sourced. Supporting resources such as student worksheets will be included as downloadable PDF files.
Our digital Simulations and Practice Tools are powerful resources for exploration, data collection, and student collaboration. They allow students the ability to explore scientific concepts that might otherwise be invisible or impossible to see with the naked eye.
Available for every unit, our Student Investigation Notebooks contain instructions for activities and space for students to record data and observations, reflect on ideas from texts and investigations, and construct explanations and arguments.
In grades 6–8, one copy of the Student Investigation Notebook is included in each unit’s materials kit for use as a blackline master. Each notebook is also available as a downloadable PDF on the Unit Guide page of the digital Teacher’s Guide.
These customizable PowerPoints are available for every lesson of the program and make delivering instruction a snap with visual prompts, colorful activity instructions, investigation set-up videos and animations, and suggested teacher talk in the notes section of each slide.
Full coverage of the Oregon Science Standards
Amplify Science was designed from the ground up to meet the Next Generation Science Standards (NGSS). As such, it aligns to the Oregon Science Standards, which were also borne out of the NGSS.
The guidance below is meant to provide support for integrating additional activities that support full coverage of Oregon’s standards. Organized by grade level, each section below will outline:
- Additional activities that support 100% alignment to the Oregon Science Standards.
- The standard being addressed with the activities.
- The recommended placement of the activities within a specific Amplify Science unit.
- PDFs of any accompanying materials that are necessary to implement the activities.
Activity Title: Meet a Scientist Who Changed How We Think About Brain Cells
About this activity: In this activity, students read a short article about a scientist who studied the nervous system.
Recommended placement: Metabolism unit, Lesson 3.2
Materials:
Instructions: Download the PDF “Meet a Scientist Who Changed How We Think About Brain Cells” above and remind students of the Active Reading guidelines. Before students read the article, invite them to share prior experiences. Then have students complete the copymaster above.
Activity Title: Meet a Scientist Who Studies Underwater Currents
About this activity: In this activity, students read a short article about a scientist who studies ocean currents.
Recommended placement: Oceans, Atmosphere, and Climate unit, Lesson 2.1
Materials:
Instructions: Download the PDF “Meet a Scientist Who Studies Underwater Currents” above and remind students of the Active Reading guidelines. Before students read the article, invite them to share prior experiences. Then have students complete the copymaster above.
Activity Title: Meet a Scientist Who Studies How the Environment Affects Our Traits
About this activity: In this activity, students read two short articles, one about current research on genes and proteins, and one about a scientist who is studying how the environment can affect our traits.
Recommended placement: Traits and Reproduction unit, Lesson 2.4
Materials:
Instructions: Download the PDF “Meet a Scientist Who Studies How the Environment Affects Our Traits” above and remind students of the Active Reading guidelines. Before students read the article, invite them to share prior experiences. Then have students complete the copymaster above.
Activity Title: Who Becomes a Space Scientist?
About this activity: In this activity, Students read a short article about a scientist who studies space.
Recommended placement: Geology on Mars unit, Lesson 3.1
Materials:
Instructions: Download the PDF “Who Becomes a Space Scientist?” above and remind students of the Active Reading guidelines. Before students read the article, invite them to share prior experiences. Then have students complete the copymaster above.
Activity Title: Meet a Scientist Who Studies How Plants Find Water Underground
About this activity: In this activity, students read a short article about a scientist who studies how plants’ roots get water.
Recommended placement: Matter and Energy in Ecosystems unit, Lesson 1.6
Materials:
Instructions: Download the PDF “Meet a Scientist Who Studies How Plants Find Water Underground” above and remind students of the Active Reading guidelines. Before students read the article, invite them to share prior experiences. Then have students complete the copymaster above.
Activity Title: Bringing Back the Buffalo
About this activity: In this activity, students change one competing population to try to decrease the other in the Sim, and read a short article about a scientist who studies buffalo.
Recommended placement: Populations and Resources unit, Lesson 3.2
Materials:
Instructions: Download the PDF “Bringing Back the Buffalo” above and remind students of the Active Reading guidelines. Before students read the article, invite them to share prior experiences. Then have students complete the copymaster above.
Activity Title: Rereading “A Continental Puzzle”
About this activity: In this activity, students reread “A Continental Puzzle” and think about how patterns were helpful to Wegener’s work.
Recommended placement: Plate Motion unit, Lesson 3.2
Materials:
Instructions: Direct students back to “A Continental Puzzle” above and remind students of the Active Reading guidelines. Before students re-read the article, invite them to share prior experiences. Then have students complete the copymaster above.
Activity Title: Meet a Scientist Who Studies Variation in Monkey Populations
About this activity: In this activity, students read a short article about a scientist who studies variation of traits in monkey populations.
Recommended placement: Natural Selection unit, Lesson 1.6
Materials:
Instructions: Download the PDF “Meet a Scientist Who Studies Variation in Monkey Populations” above and remind students of the Active Reading guidelines. Before students read the article, invite them to share prior experiences. Then have students complete the copymaster above.
Activity Title: Extinctions and Human Impacts
About this activity: The purpose of this lesson is for students to see how increases in human population and consumption of natural resources can negatively impact Earth’s systems.
Recommended placement: Natural Selection unit, Lesson 4.5
Materials:
Instructions: Download the PDF “Extinctions and Human Impacts” above and remind students of the Active Reading guidelines. Before students read the article, invite them to share prior experiences. Then have students complete the copymaster above.
Activity Title: Steno and the Shark
About this activity: In this activity, students read a short article about Nicolas Steno, a scientist from the 1600s whose studies of fossilized sharks’ teeth embedded in rock layers laid the foundation for the modern understanding of stratigraphy.
Recommended placement: Evolutionary History unit, Lesson 2.4
Materials:
Instructions: Download the PDF “Steno and the Shark” above and remind students of the Active Reading guidelines. Before students read the article, invite them to share prior experiences. Then have students complete the copymaster above.
Activity Title: Scale in the Solar System
About this activity: In this activity, students read and annotate the articles “Scale in the Solar System” and “The Solar System Is Huge.”
Recommended placement: Earth, Moon, and Sun unit, Lesson 1.2
Materials:
Instructions: Download the PDF “Scale in the Solar System” above and remind students of the Active Reading guidelines. Before students read the article, invite them to share prior experiences. Then have students complete the copymaster above.
Explore your print samples
With your Amplify Science print samples, you’ll find unit-specific Teacher’s References Guides and Student Investigation Notebooks for each grade level.
A note about the Teacher’s Reference Guides:
It’s important that your committee sees the full breadth and depth of our instruction. For that reason, we provided a copy of each of our unit-specific Teacher Reference Guides.
Rest assured that teachers do not use these robust reference guides for day-to-day teaching. For that, we have a hands-free TG!
- Teacher Reference Guide: Unlike a typical TG that requires a series of supplemental books to support it, our encyclopedic reference guide is chock-full of everything a teacher needs to fully implement our program and the NGSS.
- Ready-to-Teach Lesson Slides: For daily instruction, teachers need their hands free. That’s why we created ready-to-teach lesson slides for every single lesson. What’s more, they are editable and include suggested teacher talk and point-of-use differentiation and other instructional tips. Click to learn more.
A note about the Materials Kits:
Hands-on learning is at the heart of Amplify Science, and is integrated into every unit. In order to make hands-on learning more manageable for busy teachers, Amplify Science materials are organized into unit-specific kits.
Our unit-specific kits:
- Include more materials — We give teachers enough materials to support 200 student uses.
- Are more manageable — Unlike other programs that require large groups of students to share limited sets of materials, our kits include enough to support small groups of 4–5 students.
- Include supportive videos — Each hands-on activity provides clear instructions for the teacher, with more complex activities supported by video demonstrations and illustrations.
At your request, we did not include our materials kits with our submissions samples. However, we did provide grade-specific lists of all materials included in each kit, which you can also find with the links below.
Access your digital samples
Explore as a teacher
Follow these instructions to explore the Amplify Science digital platform as a teacher.
- Click the Access Amplify Science Platform button below and bookmark it.
- Select Log in with Amplify.
- Enter the username: t.or68sci@tryamplify.net
- Enter the password: Science5OR
- Click the Science icon.
- Click on the Grade Menu in the top center of the screen and select any grade.
- Select any unit.
To help familiarize yourself with navigating the digital platform, watch the below navigational video.
Explore as a student
Follow these instructions to explore the Amplify Science digital platform as a student.
- Click the Access Amplify Science Platform button below and bookmark it.
- Select Log in with Amplify.
- Enter the username: s.or68sci@tryamplify.net
- Enter the password: Science5OR
- Click the Science icon.
- Click on the Grade Menu in the top center of the screen and select any grade.
- Select any unit.
Resources to support your review
- Oregon standards correlation for grades 6–8
- QCD Science Adoption Criteria 2022 for grades 6-8
- QCD IMET Citation guidance for grades 6-8
- Oregon Science IMET for grades 6-8 (Excel download)
- Oregon QCD-IMET Citation guidance for grades 6-8
- Research behind Amplify Science
- Phenomena in grades 6–8
- Program structure for grades 6–8
- Active Reading in grades 6–8
- Engineering in Amplify Science
- Approaches to assessment in grades 6–8
New Mexico Educators: Welcome to Amplify Science 6–8!
Amplify Science is an engaging core curriculum designed for three-dimensional, phenomena-based learning that is rated ‘all green’ on EdReports.
With Amplify Science, New Mexico students don’t just passively learn about science concepts. Instead, they take on the role of scientists and engineers to actively investigate and figure out real-world phenomena. They do this through a blend of cohesive and compelling storylines, hands-on investigations, collaborative discussions, literacy-rich activities, and interactive digital tools.
Amplify Science Success Story
The Lawrence Hall of Science
Developed by the science education experts at UC Berkeley’s Lawrence Hall of Science and the digital learning team at Amplify, our program features:
- A phenomena-based approach where students construct a complex understanding of each unit’s anchor phenomenon.
- A blend of cohesive storylines, hands-on investigations, rich discussions, literacy-rich activities, and digital tools.
- Carefully crafted units, chapters, lessons, and activities designed to deliver true 3-dimensional learning.
- An instructional design that supports all learners in accessing all standards.
Instructional model
The Amplify Science program is rooted in the proven, research-based pedagogy of Do, Talk, Read, Write, Visualize. Here’s how each element works:
Do
First-hand investigations are an important part of any science classroom, and Amplify Science has students getting hands-on in every unit—from building models of protein molecules to experimenting with electrical systems.
Talk
Student-to-student discourse and full-class discussions are an integral part of the program. Students are provided with numerous opportunities to engage in meaningful oral scientific argumentation, all while fostering a collaborative classroom environment.
Read
Students read scientific articles, focusing their reading activities on searching for evidence related to their investigation and, importantly, on asking and recording questions as they read through fascinating texts on 21st-century topics.
Write
Following real-world practices, students write scientific arguments based on evidence they’ve collected, making clear their reasoning about how a given piece of evidence connects to one of several claims.
Visualize
By manipulating digital simulations and using modeling tools to craft visualizations of their thinking— just as real scientists and engineers do—students take their learning far beyond the confines of what they can physically see in the classroom in an exciting and authentic way.
Program structure
Our cyclical lesson design ensures students receive multiple exposures to concepts through a variety of modalities. As they progress through the lessons within a unit, students build and deepen their understanding, increasing their ability to develop and refine complex explanations of the unit’s phenomenon.
It’s this proven program structure and lesson design that enables Amplify Science to address 100% of the NGSS and support students in mastering the New Mexico STEM Ready! Science Standards.
Unit types
While every unit delivers three-dimensional learning experiences and engages students in gathering evidence from a rich collection of sources, each unit also serves a unique instructional purpose.
In grades 6–8:
- One unit is a launch unit.
- Three units are core units.
- Two units are engineering internships.
Launch units are the first units taught in each year of Amplify Science. The goal of the Launch unit is to introduce students to norms, routines, and practices that will be built on throughout the year, including argumentation, active reading, and using the program’s technology. For example, rather than taking the time to explain the process of active reading in every unit in a given year, it is explained thoroughly in the Launch unit, thereby preparing students to read actively in all subsequent units.
Core units establish the context of the unit by introducing students to a real-world problem. As students move through lessons in a Core unit, they figure out the unit’s anchoring phenomenon, gain an understanding of the unit’s disciplinary core ideas and science and engineering practices, and make linkages across topics through the crosscutting concepts. Each Core unit culminates with a Science Seminar and final writing activity.
Engineering Internship units invite students to design solutions for real-world problems as interns for a fictional company called Futura. Students figure out how to help those in need, from tsunami victims in Sri Lanka to premature babies, through the application of engineering practices. In the process, they apply and deepen their learning from Core units.
Unit sequence
Our lessons follow a structure that is grounded in regular routines while still being flexible enough to allow for a variety of learning experiences.
In fact, our multi-modal instruction offers more opportunities for students to construct meaning, and practice and apply concepts than any other program. What’s more, our modular design means our units can be flexibly arranged to support your instructional goals.
Program components
Available digitally and in print, our unit-specific reference guides are chock full of helpful resources, including scientific background knowledge, planning information and resources, color-coded 3-D Statements, detailed lesson plans, tips for delivering instruction, and differentiation strategies.
Hands-on learning is an essential part of Amplify Science, and is integrated into every unit. Students actively participate in science, playing the roles of scientists and engineers as they gather evidence, think critically, solve problems, and develop and defend claims about the world around them. Every unit includes hands-on investigations that are critical to achieving the unit’s learning goals.
More hands-on with Flextensions:
Hands-on Flextensions are additional, optional investigations that are included at logical points in the learning progression and give students an opportunity to dig deeper if time permits. These activities offer teachers flexibility to choose to dedicate more time to hands-on learning. Materials referenced in Hands-on Flextension activities will either be included in the unit kit or are easily sourced. Supporting resources such as student worksheets will be included as downloadable PDF files.
Our kits include enough materials to support 200 student uses. In other words, teachers can easily support all five periods and small groups of 4-5 students each. Plus, our unit-specific kits mean teachers just grab the tub they need and then put it all back with ease.
Our digital Simulations and Practice Tools are powerful resources for exploration, data collection, and student collaboration. They allow students the ability to explore scientific concepts that might otherwise be invisible or impossible to see with the naked eye.
Available for every unit, our Student Investigation Notebooks contain instructions for activities and space for students to record data and observations, reflect on ideas from texts and investigations, and construct explanations and arguments.
In grades 6–8, one copy of the Student Investigation Notebook is included in each unit’s materials kit for use as a blackline master. Each notebook is also available as a downloadable PDF on the Unit Guide page of the digital Teacher’s Guide.
These customizable PowerPoints are available for every lesson of the program and make delivering instruction a snap with visual prompts, colorful activity instructions, investigation set-up videos and animations, and suggested teacher talk in the notes section of each slide.
Full coverage of NGSS and New Mexico STEM Ready! Science Standards
Amplify Science was designed from the ground up to meet the Next Generation Science Standards (NGSS). As such, it aligns to the New Mexico Science Standards, which were also borne out of the NGSS.
K-8 NGSS Correlation by Dimension
K-8 NM STEM Ready! Standards Correlation
Explore your print samples
With your Amplify Science print samples, you’ll find unit-specific Teacher’s References Guides and Student Investigation Notebooks for each grade level.
A note about the Teacher’s Reference Guides:
It’s important that your committee sees the full breadth and depth of our instruction. For that reason, we provided a copy of each of our unit-specific Teacher Reference Guides.
Rest assured that teachers do not use these robust reference guides for day-to-day teaching. For that, we have a hands-free Teacher Guide!
- Teacher Reference Guide: Unlike a typical Teacher Guide that requires a series of supplemental books to support it, our encyclopedic reference guide is chock-full of everything a teacher needs to fully implement our program and the NGSS.
- Ready-to-Teach Lesson Slides: For daily instruction, teachers need their hands free. That’s why we created ready-to-teach lesson slides for every single lesson. What’s more, they are editable and include suggested teacher talk and point-of-use differentiation and other instructional tips. Click to learn more.
A note about the Materials Kits:
Hands-on learning is at the heart of Amplify Science, and is integrated into every unit. In order to make hands-on learning more manageable for busy teachers, Amplify Science materials are organized into unit-specific kits.
Our unit-specific kits:
- Include more materials — We give teachers enough materials to support 200 student uses.
- Are more manageable — Unlike other programs that require large groups of students to share limited sets of materials, our kits include enough to support small groups of 4–5 students.
- Include supportive videos — Each hands-on activity provides clear instructions for the teacher, with more complex activities supported by video demonstrations and illustrations.
Access your digital samples
Explore as a teacher
Follow these instructions to explore the Amplify Science digital platform as a teacher.
- Click the Access Amplify Science Platform button below and bookmark it.
- Select Log in with Amplify.
- Enter the username: t20.sci6-8@tryamplify.net
- Enter the password: AmplifyNumber1
- Click on Science in Your Programs
- Click on the Program drop-down menu and select your desired domain
- Select any unit.
To help familiarize yourself with navigating the digital platform, watch the below navigational video.
Explore as a student
Follow these instructions to explore the Amplify Science digital platform as a student.
- Click the Access Amplify Science Platform button below and bookmark it.
- Select Log in with Amplify.
- Enter the username: s20.sci6-8@tryamplify.net
- Enter the password: AmplifyNumber1
- Click Science in Your Programs
- Click on the Program drop-down menu and select your desired domain
- Select any unit title.
Additional resources to support your review
Welcome to Amplify Science 6–8!
Amplify Science is an engaging core curriculum designed for three-dimensional, phenomena-based learning.
With Amplify Science, Detroit students don’t just passively learn about science concepts. Instead, they take on the role of scientists and engineers to actively investigate and figure out real-world phenomena. They do this through a blend of cohesive and compelling storylines, hands-on investigations, collaborative discussions, literacy-rich activities, and interactive digital tools.
What is Amplify Science?
The Lawrence Hall of Science
Developed by the science education experts at UC Berkeley’s Lawrence Hall of Science and the digital learning team at Amplify, our program features:
- A phenomena-based approach where students construct a complex understanding of each unit’s anchor phenomenon.
- A blend of cohesive storylines, hands-on investigations, rich discussions, literacy-rich activities, and digital tools.
- Carefully crafted units, chapters, lessons, and activities designed to deliver true three-dimensional learning.
- An instructional design that supports all learners in accessing all standards.
Proven to work
Instructional model
The Amplify Science program is rooted in the proven, research-based pedagogy of Do, Talk, Read, Write, Visualize. Here’s how each element works:
Do
First-hand investigations are an important part of any science classroom, and Amplify Science has students getting hands-on in every unit—from building models of protein molecules to experimenting with electrical systems.
Talk
Student-to-student discourse and full-class discussions are an integral part of the program. Students are provided with numerous opportunities to engage in meaningful oral scientific argumentation, all while fostering a collaborative classroom environment.
Read
Students read scientific articles, focusing their reading activities on searching for evidence related to their investigation and, importantly, on asking and recording questions as they read through fascinating texts on 21st-century topics.
Write
Following real-world practices, students write scientific arguments based on evidence they’ve collected, making clear their reasoning about how a given piece of evidence connects to one of several claims.
Visualize
By manipulating digital simulations and using modeling tools to craft visualizations of their thinking— just as real scientists and engineers
do—students take their learning far beyond the confines of what they can physically see in the classroom in an exciting and authentic way.
Program structure
Our cyclical lesson design ensures students receive multiple exposures to concepts through a variety of modalities. As they progress through the lessons within a unit, students build and deepen their understanding, increasing their ability to develop and refine complex explanations of the unit’s phenomenon.
It’s this proven program structure and lesson design that enables Amplify Science to address 100% of the Next Generation Science Standards (NGSS) and support students in mastering the Pennsylvania Science Standards.
Unit types
While every unit delivers three-dimensional learning experiences and engages students in gathering evidence from a rich collection of sources, each unit also serves a unique instructional purpose.
In grades 6–8:
- One unit is a launch unit.
- Three units are core units.
- Two units are engineering internships.
Launch units are the first units taught in each year of Amplify Science. The goal of the Launch unit is to introduce students to norms, routines, and practices that will be built on throughout the year, including argumentation, active reading, and using the program’s technology. For example, rather than taking the time to explain the process of active reading in every unit in a given year, it is explained thoroughly in the Launch unit, thereby preparing students to read actively in all subsequent units.
Core units establish the context of the unit by introducing students to a real-world problem. As students move through lessons in a Core unit, they figure out the unit’s anchoring phenomenon, gain an understanding of the unit’s disciplinary core ideas and science and engineering practices, and make linkages across topics through the crosscutting concepts. Each Core unit culminates with a Science Seminar and final writing activity.
Engineering Internship units invite students to design solutions for real-world problems as interns for a fictional company called Futura. Students figure out how to help those in need, from tsunami victims in Sri Lanka to premature babies, through the application of engineering practices. In the process, they apply and deepen their learning from Core units.
Unit sequence
Our lessons follow a structure that is grounded in regular routines while still being flexible enough to allow for a variety of learning experiences.
In fact, our multi-modal instruction offers more opportunities for students to construct meaning, and practice and apply concepts than any other program. What’s more, our modular design means our units can be flexibly arranged to support your instructional goals.
Program components
Available digitally and in print, our unit-specific reference guides are chock-full of helpful resources, including scientific background knowledge, planning information and resources, color-coded 3D Statements, detailed lesson plans, tips for delivering instruction, and differentiation strategies.
Hands-on learning is an essential part of Amplify Science, and is integrated into every unit. Students actively participate in science, playing the roles of scientists and engineers as they gather evidence, think critically, solve problems, and develop and defend claims about the world around them. Every unit includes hands-on investigations that are critical to achieving the unit’s learning goals.
More hands-on with Flextensions:
Hands-on Flextensions are additional, optional investigations that are included at logical points in the learning progression and give students an opportunity to dig deeper if time permits. These activities offer teachers flexibility to choose to dedicate more time to hands-on learning. Materials referenced in Hands-on Flextension activities will either be included in the unit kit or are easily sourced. Supporting resources such as student worksheets will be included as downloadable PDF files.
Our kits include enough materials to support 200 student uses. In other words, teachers can easily support all five periods and small groups of 4-5 students each. Plus, our unit-specific kits mean teachers just grab the tub they need and then put it all back with ease.
Our digital Simulations and Practice Tools are powerful resources for exploration, data collection, and student collaboration. They allow students the ability to explore scientific concepts that might otherwise be invisible or impossible to see with the naked eye.
Available for every unit, our Student Investigation Notebooks contain instructions for activities and space for students to record data and observations, reflect on ideas from texts and investigations, and construct explanations and arguments.
In grades 6–8, one copy of the Student Investigation Notebook is included in each unit’s materials kit for use as a blackline master. Each notebook is also available as a downloadable PDF on the Unit Guide page of the digital Teacher’s Guide.
These customizable PowerPoints are available for every lesson of the program and make delivering instruction a snap with visual prompts, colorful activity instructions, investigation set-up videos and animations, and suggested teacher talk in the notes section of each slide.
Explore your print samples
With your Amplify Science print samples, you’ll find unit-specific Teacher’s References Guides and Student Investigation Notebooks for each grade level.
A note about the Teacher’s Reference Guides:
It’s important that your committee sees the full breadth and depth of our instruction. For that reason, we provided a copy of each of our unit-specific Teacher Reference Guides.
Rest assured that teachers do not use these robust reference guides for day-to-day teaching. For that, we have a hands-free TG!
- Teacher Reference Guide: Unlike a typical TG that requires a series of supplemental books to support it, our encyclopedic reference guide is chock-full of everything a teacher needs to fully implement our program and the NGSS.
- Ready-to-Teach Lesson Slides: For daily instruction, teachers need their hands free. That’s why we created ready-to-teach lesson slides for every single lesson. What’s more, they are editable and include suggested teacher talk and point-of-use differentiation and other instructional tips. Click to learn more.
A note about the Materials Kits:
Hands-on learning is at the heart of Amplify Science, and is integrated into every unit. In order to make hands-on learning more manageable for busy teachers, Amplify Science materials are organized into unit-specific kits.
Our unit-specific kits:
- Include more materials — We give teachers enough materials to support 200 student uses.
- Are more manageable — Unlike other programs that require large groups of students to share limited sets of materials, our kits include enough to support small groups of 4–5 students.
- Include supportive videos — Each hands-on activity provides clear instructions for the teacher, with more complex activities supported by video demonstrations and illustrations.
At your request, we did not include our materials kits with our submissions samples. However, we did provide grade-specific lists of all materials included in each kit, which you can also find with the links below.
Access your digital samples
Explore as a teacher
Follow these instructions to explore the Amplify Science digital platform as a teacher.
- Click the Access Amplify Science Platform button below and bookmark it.
- Select Log in with Amplify.
- Enter the username: t1.dps68sci@demo.tryamplify.net
- Enter the password: Amplify1-dps68sci
- Click the Science icon.
- Click on the Grade Menu in the top center of the screen and select any grade.
- Select any unit.
To help familiarize yourself with navigating the digital platform, watch the below navigational video.
Spanish-language support
Amplify Science is committed to providing support to meet the needs of all learners, including multiple access points for Spanish-speaking students. Developed in conjunction with Spanish-language experts and classroom teachers, several components are available in Spanish across the Amplify Science curriculum.
Spanish-language materials include:
| COMPONENT | TEACHER/STUDENT |
| Student Investigation Notebooks | Student |
| Science articles | Student |
| Video Transcripts | Student |
| Digital simulation translation keys | Student |
| Printed classroom materials Unit and chapter questions, key concepts, vocabulary cards, etc. | Teacher |
| Copymasters | Teacher |
| Assessments | Teacher |
| Digital student experience license This license gives students access to the student resources in Spanish, including instructional text, articles, and assessments. Teachers can control student access to Spanish-language content through the digital Teacher’s Guide. | Teacher |
| Spanish teacher support license This license includes teacher talk, projections, downloadable PDFs of all print resources, and video transcripts and closed captioning in Spanish. | Teacher |
Explore as a student
Follow these instructions to explore the Amplify Science digital platform as a student.
- Click the Access Amplify Science Platform button below and bookmark it.
- Select Log in with Amplify.
- Enter the username: s1.dpsscience@demo.tryamplify.net
- Enter the password: Amplify1-dpsscience
- Click the Science icon.
- Click on the Grade Menu in the top center of the screen and select any grade.
- Select any unit.
Resources to support your review
Core Principles:
These core principles guide our operations, employee behavior and product development:
- Customer Control: We help school districts securely manage their personally identifiable student information. The districts direct our use of the data, and control who has access to that data and with whom it is shared.
- Educational Purpose: Personal student information can only be used for customer-authorized purposes to support student learning through the secure and effective operation of our educational tools.
- Transparency: School districts, teachers, parents and students have the right to know what information is collected by school technology, how it is used and by whom, as clearly described in our privacy policy.
- Commitment: Privacy and security are thoroughly embedded into our organizational practices. We dedicate substantial resources to systems, processes and personnel required to protect student information.
Amplify Data Privacy and Security Practices:
Amplify maintains a customer data privacy policy that explains our data collection, handling and use practices.
Amplify also maintains a data security policy that explains how student data is protected from unauthorized access. Data security practices at Amplify are developed and maintained in accordance with the internationally recognized ISO27002 security standards. In addition, Amplify has successfully completed the SOC 2 Type 2 examination of controls relevant to security and conducts such examination on an annual basis.
For more information, please review our customer privacy policy and security practices. If you have additional questions, please contact us at privacy@amplify.com.
State Law Compliance
Amplify has entered into Data Privacy Agreements (DPAs) with districts across the country to facilitate compliance with applicable laws governing student data privacy. These DPAs can be applied to any Amplify product.
Unless otherwise noted, the DPAs are based on the Student Data Privacy Consortium’s (SDPC) model agreement which was created to simplify the contracting process between providers and local education agencies (LEAs) while ensuring LEAs have the necessary data protection obligations in place with providers. For additional information please visit the SDPC website and select your state.
General Offer of Privacy Terms:
To expedite your district’s need for a DPA and streamline the contracting process, we have compiled the following DPAs, listed by state.
By executing the General Offer of Privacy Terms, your LEA can “piggy back” off an existing DPA that other LEAs in your state have already agreed to. If you do not see your state below, please contact privacy@amplify.com.
Instructions:
(i) Please download the General Offer of Privacy Terms, (ii) sign and send the executed copy to your Amplify account representative, and (iii) retain a copy for your records. If you have any questions please reach out to privacy@amplify.com.
*Please note, states marked with an asterisk do not have a General Offer of Privacy Terms; however, please review the instructions below on how to quickly implement a DPA in compliance with your LEA’s state law.
Arizona: To enter into Amplify’s AZ-NDPA-V1, please sign the General Offer of Privacy Terms
Arkansas: To enter into Amplify’s AR-NDPA-V1, please sign the and General Offer of Privacy Terms
California: To enter into Amplify’s CA-NDPA, Version 1.5, please sign the General Offer of Privacy Terms
Connecticut*
To facilitate your district’s compliance with the requirements of Connecticut’s student data privacy law (Connecticut General Statutes §§ 10-234aa through 10-234dd), Amplify is proud to offer our “Connecticut Terms of Service Addendum” linked below. This Addendum supplements Amplify’s Terms and Conditions for use of Amplify products licensed by the district available at https://amplify.com/customer-terms.
Addendum: Connecticut Terms of Service Addendum
Instructions: Please retain a copy for your records – no further action is required.
Florida: To enter into Amplify’s FL-NDPA, Version 1.0, please sign the General Offer of Privacy Terms
Hawaii*
Amplify has entered into a Data Sharing Agreement with the Hawaii State Department of Education (HIDOE) which applies to any LEA associated with HIDOE. If your LEA is not a part of the HIDOE and you require a data privacy agreement, please reach out to privacy@amplify.com.
Illinois: To enter into Amplify’s IL-NDPA (which includes the IL State Supplemental Terms), please sign the General Offer of Privacy Terms
Iowa: To enter into Amplify’s IA-NDPA (which includes the IA State Supplemental Terms), please sign the General Offer of Privacy Terms
Maine: To enter into Amplify’s MA-ME-MO-NH-NY-OH-RI-VT DPA, Version 1 (which includes the ME State Supplemental Terms), please sign the General Offer of Privacy Terms
Massachusetts: To enter into Amplify’s MA-ME-MO-NH-NY-OH-RI-VT DPA, Version 1 (which includes the MA State Supplemental Terms), please sign the General Offer of Privacy Terms
Missouri: To enter into Amplify’s MO-NDPA, Version 1.0, please sign the General Offer of Privacy Terms
Montana: To enter into Amplify’s MT DPA, Version 3, please sign the General Offer of Privacy Terms
Nebraska: To enter into Amplify’s NE NDPA (which includes the NE State Supplemental Terms), please sign the General Offer of Privacy Terms
New York*
Option 1:
To facilitate your district’s compliance with the requirements of New York State Education Law § 2-D and regulations promulgated thereunder, Amplify is proud to offer our “New York Data Privacy and Security Addendum” linked below. This Addendum supplements Amplify’s Terms and Conditions for use of Amplify products licensed by the educational agency available at https://amplify.com/customer-terms.
Addendum: New York Data Privacy and Security Addendum
Instructions: Please retain a copy for your records- no further action is required.
Option 2:
To enter into Amplify’s MA-ME-MO-NH-NY-OH-RI-VT DPA, Version 1 (which includes the NY State Supplemental Terms), please sign the General Offer of Privacy Terms
New Hampshire: To enter into Amplify’s MA-ME-MO-NH-NY-OH-RI-VT DPA, Version 1 (which includes the NH State Supplemental Terms), please sign the General Offer of Privacy Terms
North Carolina*
The Data Confidentiality and Security Agreement issued by the North Carolina Department of Public Instruction (NCDPI) is not applicable to Amplify’s services given Amplify does not have a direct integration to any state system via API/plugin. You can review the NCDPI guidance here: https://www.dpi.nc.gov/about-dpi/technology-services/third-party-data-integration. However, Amplify can sign this form with some revisions. As such, we have prepared an Addendum which supplements the Data Confidentiality and Security Agreement.
Instructions: Please download a copy of the Data Confidentiality and Security Agreement with Amplify Addendum, return an executed copy to your account executive, and retain a copy for your records.
Ohio: To enter into Amplify’s OH-NDPA Version 1.0, please sign the General Offer of Privacy Terms
Oregon: To enter into Amplify’s OR-NDPA-V1, please sign the General Offer of Privacy Terms
Rhode Island: To enter into Amplify’s MA-ME-MO-NH-NY-OH-RI-VT DPA, Version 1 (which includes the RI State Supplemental Terms), please sign the General Offer of Privacy Terms
Tennessee: To enter into Amplify’s TN-NDPA-V1, please sign the General Offer of Privacy Terms
Texas: To enter into Amplify’s TX-NDPA-V1R6, please sign the General Offer of Privacy Terms
Utah: To enter into Amplify’s UT-NDPA, Version 1, please sign the General Offer of Privacy Terms
Vermont: To enter into Amplify’s MA-ME-MO-NH-NY-OH-RI-VT DPA, Version 1 (which includes the VT State Supplemental Terms), please sign the General Offer of Privacy Terms
Virginia: To enter into Amplify’s VA-DPA, please sign the General Offer of Privacy Terms
Washington: To enter into Amplify’s WA-NDPA, Version 1, please sign the General Offer of Privacy Terms
Wisconsin: To enter into Amplify’s WI SDPA, Version 1, please sign the General Offer of Privacy Terms
Wyoming: To enter into Amplify’s WY-NDPA-V1, please sign the General Offer of Privacy Terms
What’s New for Amplify Science 6–8!
Denver Public Schools (DPS), check out what’s new from Amplify Science 6-8! The first part of this site will take you through the updates that have been made to Amplify Science. The second will be a refresher of Amplify Science for any new users in DPS. With Amplify Science, DPS students don’t just passively learn about science concepts. Instead, they take on the role of scientists and engineers to actively investigate and figure out real-world phenomena. With culturally sustaining pedagogy, Amplify Science strives to make sure every student feels included in the science classroom.
Update: The Digital Experience
The digital experience allows students to engage with digital lessons and provides teachers with everything they need in one place—ready-to-use slides-based lessons, seamlessly integrated teacher prompts and guidance, robust PD resources, and more. It’s now easier and more engaging than ever to plan lessons, present digital content, and review student work. To learn more, click here.
Update: The PD Library
All professional development (PD) content is consolidated into the PD Library, a one-stop hub for all your self-paced PD needs. As a result, the “Professional Learning Resources” tile will no longer be available on the main Amplify Science Program Hub page. The rest of the non-PD content in the Program Hub will remain as is, including the on-demand resources.
Update: Educator & Student Home expansion
Educator and Student Home landing pages will now be available for all Amplify Science users. This Home page provides a central location to access all Amplify programs in one place and a customized stream based on your activity.
Your Amplify Science grades 6–8 students will no longer access My Work for assignments, scores, and teacher feedback. Instead, they’ll find it all on Student Home, the page they already land on when logging in to Amplify Science.
Keep in mind: Amplify Science middle school teachers will continue to have access to Classwork.
Update: Caregiver Hub
Throughout the school year, teachers can share the Amplify Science Caregiver Hub with students’ families. This site provides curriculum details, an overview of what caregivers can expect throughout the school year, and resources they can use with students at home.
What is Amplify Science?
The Lawrence Hall of Science
Developed by the science education experts at UC Berkeley’s Lawrence Hall of Science and the digital learning team at Amplify, our program features:
- A phenomena-based approach where students construct a complex understanding of each unit’s anchor phenomenon.
- A blend of cohesive storylines, hands-on investigations, rich discussions, literacy-rich activities, and digital tools.
- Carefully crafted units, chapters, lessons, and activities designed to deliver true three-dimensional learning.
- An instructional design that supports all learners in accessing all standards.
Proven to work
Instructional model
The Amplify Science program is rooted in the proven, research-based pedagogy of Do, Talk, Read, Write, Visualize. Here’s how each element works:
Do
First-hand investigations are an important part of any science classroom, and Amplify Science has students getting hands-on in every unit—from building models of protein molecules to experimenting with electrical systems.
Talk
Student-to-student discourse and full-class discussions are an integral part of the program. Students are provided with numerous opportunities to engage in meaningful oral scientific argumentation, all while fostering a collaborative classroom environment.
Read
Students read scientific articles, focusing their reading activities on searching for evidence related to their investigation and, importantly, on asking and recording questions as they read through fascinating texts on 21st-century topics.
Write
Following real-world practices, students write scientific arguments based on evidence they’ve collected, making clear their reasoning about how a given piece of evidence connects to one of several claims.
Visualize
By manipulating digital simulations and using modeling tools to craft visualizations of their thinking— just as real scientists and engineers
do—students take their learning far beyond the confines of what they can physically see in the classroom in an exciting and authentic way.
Program structure
Our cyclical lesson design ensures students receive multiple exposures to concepts through a variety of modalities. As they progress through the lessons within a unit, students build and deepen their understanding, increasing their ability to develop and refine complex explanations of the unit’s phenomenon.
It’s this proven program structure and lesson design that enables Amplify Science to address 100% of the Next Generation Science Standards (NGSS) and support students in mastering the Pennsylvania Science Standards.
Unit types
While every unit delivers three-dimensional learning experiences and engages students in gathering evidence from a rich collection of sources, each unit also serves a unique instructional purpose.
In grades 6–8:
- One unit is a launch unit.
- Three units are core units.
- Two units are engineering internships.
Launch units are the first units taught in each year of Amplify Science. The goal of the Launch unit is to introduce students to norms, routines, and practices that will be built on throughout the year, including argumentation, active reading, and using the program’s technology. For example, rather than taking the time to explain the process of active reading in every unit in a given year, it is explained thoroughly in the Launch unit, thereby preparing students to read actively in all subsequent units.
Core units establish the context of the unit by introducing students to a real-world problem. As students move through lessons in a Core unit, they figure out the unit’s anchoring phenomenon, gain an understanding of the unit’s disciplinary core ideas and science and engineering practices, and make linkages across topics through the crosscutting concepts. Each Core unit culminates with a Science Seminar and final writing activity.
Engineering Internship units invite students to design solutions for real-world problems as interns for a fictional company called Futura. Students figure out how to help those in need, from tsunami victims in Sri Lanka to premature babies, through the application of engineering practices. In the process, they apply and deepen their learning from Core units.
DPS Scope and Sequence
Our lessons follow a structure that is grounded in regular routines while still being flexible enough to allow for a variety of learning experiences.
In fact, our multi-modal instruction offers more opportunities for students to construct meaning, and practice and apply concepts than any other program. What’s more, our modular design means our units can be flexibly arranged to support your instructional goals.
Program components
Available digitally and in print, our unit-specific reference guides are chock-full of helpful resources, including scientific background knowledge, planning information and resources, color-coded 3D Statements, detailed lesson plans, tips for delivering instruction, and differentiation strategies.
Hands-on learning is an essential part of Amplify Science, and is integrated into every unit. Students actively participate in science, playing the roles of scientists and engineers as they gather evidence, think critically, solve problems, and develop and defend claims about the world around them. Every unit includes hands-on investigations that are critical to achieving the unit’s learning goals.
More hands-on with Flextensions:
Hands-on Flextensions are additional, optional investigations that are included at logical points in the learning progression and give students an opportunity to dig deeper if time permits. These activities offer teachers flexibility to choose to dedicate more time to hands-on learning. Materials referenced in Hands-on Flextension activities will either be included in the unit kit or are easily sourced. Supporting resources such as student worksheets will be included as downloadable PDF files.
Our kits include enough materials to support 200 student uses. In other words, teachers can easily support all five periods and small groups of 4-5 students each. Plus, our unit-specific kits mean teachers just grab the tub they need and then put it all back with ease.
Our digital Simulations and Practice Tools are powerful resources for exploration, data collection, and student collaboration. They allow students the ability to explore scientific concepts that might otherwise be invisible or impossible to see with the naked eye.
Available for every unit, our Student Investigation Notebooks contain instructions for activities and space for students to record data and observations, reflect on ideas from texts and investigations, and construct explanations and arguments.
In grades 6–8, one copy of the Student Investigation Notebook is included in each unit’s materials kit for use as a blackline master. Each notebook is also available as a downloadable PDF on the Unit Guide page of the digital Teacher’s Guide.
These customizable PowerPoints are available for every lesson of the program and make delivering instruction a snap with visual prompts, colorful activity instructions, investigation set-up videos and animations, and suggested teacher talk in the notes section of each slide.
Explore your print samples
With your Amplify Science print samples, you’ll find unit-specific Teacher’s References Guides, Student Investigation Notebooks, and sets of Student Books for each grade level.
A note about the Teacher Reference Guides:
It’s important that you see the full breadth and depth of our instruction. For that reason, we provide a copy of each of our unit-specific Teacher Reference Guides.
Rest assured that teachers do not use these robust reference guides for day-to-day teaching. For that, we have a hands-free Teacher’s Guide!
- Teacher Reference Guide: Unlike a typical TG that requires a series of supplemental books to support it, our encyclopedic reference guide is chock-full of everything a teacher needs to fully implement our program and the NGSS.
- Ready-to-Teach Lesson Slides: For daily instruction, teachers need their hands free. That’s why we created ready-to-teach lesson slides for every single lesson. What’s more, they are editable and include suggested teacher talk and point-of-use differentiation and other instructional tips. Click to learn more.
A note about the Materials Kits:
Hands-on learning is at the heart of Amplify Science, and is integrated into every unit. In order to make hands-on learning more manageable for busy teachers, Amplify Science materials are organized into unit-specific kits.
Our unit-specific kits:
- Include more materials — We give teachers enough materials to support 200 student uses.
- Are more manageable — Unlike other programs that require large groups of students to share limited sets of materials, our kits include enough to support small groups of 4–5 students.
- Include supportive videos — Each hands-on activity provides clear instructions for the teacher, with more complex activities supported by video demonstrations and illustrations.
At your request, we did not include our materials kits with our submissions samples. However, we did provide grade-specific lists of all materials included in each kit, which you can also find with the links below.
Access your digital samples
Explore as a teacher
Follow these instructions to explore the Amplify Science digital platform as a teacher.
- Click the Access Amplify Science Platform button below and bookmark it.
- Select Log in with Amplify.
- Enter the username: t1.dps68sci@demo.tryamplify.net
- Enter the password: Amplify1-dps68sci
- Click the Science icon.
- Click on the Grade Menu in the top center of the screen and select any grade.
- Select any unit.
To help familiarize yourself with navigating the digital platform, watch the below navigational video.
Spanish-language support
Amplify Science is committed to providing support to meet the needs of all learners, including multiple access points for Spanish-speaking students. Developed in conjunction with Spanish-language experts and classroom teachers, several components are available in Spanish across the Amplify Science curriculum.
Spanish-language materials include:
| COMPONENT | TEACHER/STUDENT |
| Student Investigation Notebooks | Student |
| Science articles | Student |
| Video Transcripts | Student |
| Digital simulation translation keys | Student |
| Printed classroom materials Unit and chapter questions, key concepts, vocabulary cards, etc. | Teacher |
| Copymasters | Teacher |
| Assessments | Teacher |
| Digital student experience license This license gives students access to the student resources in Spanish, including instructional text, articles, and assessments. Teachers can control student access to Spanish-language content through the digital Teacher’s Guide. | Teacher |
| Spanish teacher support license This license includes teacher talk, projections, downloadable PDFs of all print resources, and video transcripts and closed captioning in Spanish. | Teacher |
Resources to support your review
- DEIA in Amplify Science
- Research behind Amplify Science
- Phenomena in grades 6–8
- Program structure for grades 6–8
- Active Reading in grades 6–8
- Engineering in Amplify Science
- Approaches to assessment in grades 6–8
Contact Us
If you have any further questions as your review Amplify Science, please contact:
Monty Lammers
Senior Account Executive
719-964-4501
mlammers@amplify.com
Welcome to Amplify Science Pennsylvania
(6–8)!
Amplify Science is an engaging core curriculum designed for three-dimensional, phenomena-based learning.
With Amplify Science, Pennsylvania students shift from learning about to figuring out science, through authentic three-dimensional (3D) learning and phenomena-based exploration. In each unit, students take on the role of a scientist or engineer to investigate a real-world problem. This prepares them to become critical thinkers who can solve problems in their communities and beyond.
What is Amplify Science Pennsylvania?
Customized lessons for Pennsylvania
Amplify Science Pennsylvania (6–8) combines our nationally recognized, proven curriculum with custom lessons specifically designed to ensure that you are meeting Pennsylvania’s STEELS standards.
The Lawrence Hall of Science
Developed by the science education experts at UC Berkeley’s Lawrence Hall of Science and the digital learning team at Amplify, our program features:
- A phenomena-based approach, in which students construct a complex understanding of each unit’s anchor phenomenon.
- A blend of cohesive storylines, hands-on investigations, rich discussions, literacy-rich activities, and digital tools.
- Carefully crafted units, chapters, lessons, and activities designed to deliver true three-dimensional learning.
- An instructional design that supports all learners in accessing all standards.
Proven to work
Instructional model
The Amplify Science Pennsylvania program is rooted in the proven, research-based pedagogy of Do, Talk, Read, Write, Visualize. Here’s how each element works:
Do
First-hand investigations are an important part of any science classroom, and Amplify Science Pennsylvania has students getting hands-on in every unit—from building models of protein molecules to experimenting with electrical systems.
Talk
Student-to-student discourse and full-class discussions are an integral part of the program. Students are provided with numerous opportunities to engage in meaningful oral scientific argumentation while fostering a collaborative classroom environment.
Read
Students read scientific articles, focusing on searching for evidence related to their investigation and on asking and recording questions as they read through fascinating texts on 21st-century topics.
Write
Following real-world practices, students write scientific arguments based on evidence they’ve collected, making clear their reasoning about how a given piece of evidence connects to one of several claims.
Visualize
By manipulating digital simulations and using modeling tools to craft visualizations of their thinking— just as real scientists and engineers
do—students take their learning far beyond the confines of what they can physically see in the classroom in an exciting and authentic way.
Program structure
Our cyclical lesson design ensures that students receive multiple exposures to concepts through a variety of modalities. As they progress through the lessons within a unit, students build and deepen their understanding, increasing their ability to develop and refine complex explanations of the unit’s phenomenon.
It’s this proven program structure and lesson design that enables Amplify Science Pennsylvania to address 100% of the Next Generation Science Standards (NGSS), and support students in mastering the Pennsylvania Science Standards.
Unit types
While every unit delivers three-dimensional learning experiences and engages students in gathering evidence from a rich collection of sources, each unit also serves a unique instructional purpose.
In grades 6–8:
- One unit is a launch unit.
- Three units are core units.
- Two units are engineering internships.
Launch units are the first units taught in each year of Amplify Science Pennsylvania. The goal of the Launch unit is to introduce students to norms, routines, and practices that will be built on throughout the year, including argumentation, active reading, and using the program’s technology. For example, rather than taking the time to explain the process of active reading in every unit in a given year, it is explained thoroughly in the Launch unit, thereby preparing students to read actively in all subsequent units.
Core units establish the context of the unit by introducing students to a real-world problem. As students move through lessons in a Core unit, they figure out the unit’s anchoring phenomenon, gain an understanding of the unit’s disciplinary core ideas and science and engineering practices, and make linkages across topics through the crosscutting concepts. Each Core unit culminates with a Science Seminar and final writing activity.
Engineering Internship units invite students to design solutions for real-world problems as interns for a fictional company called Futura. Students figure out how to help those in need, from tsunami victims in Sri Lanka to premature babies, through the application of engineering practices. In the process, they apply and deepen their learning from Core units.
Unit sequence
Our lessons follow a structure that is grounded in regular routines while still being flexible enough to allow for a variety of learning experiences.
In fact, our multimodal instruction offers more opportunities for students to construct meaning, and practice and apply concepts, than any other program. What’s more, our modular design means our units can be flexibly arranged to support your instructional goals.
Program components
Available digitally and in print, our unit-specific reference guides are chock full of helpful resources, including scientific background knowledge, planning information and resources, color-coded 3D Statements, detailed lesson plans, tips for delivering instruction, and differentiation strategies.
Hands-on learning is an essential part of Amplify Science Pennsylvania, and is integrated into every unit. Students actively participate in science, playing the roles of scientists and engineers as they gather evidence, think critically, solve problems, and develop and defend claims about the world around them. Every unit includes hands-on investigations that are critical to achieving the unit’s learning goals.
More hands-on with Flextensions:
Hands-on Flextensions are additional, optional investigations that are included at logical points in the learning progression and give students an opportunity to dig deeper if time permits. These activities offer teachers flexibility to choose to dedicate more time to hands-on learning. Materials referenced in Hands-on Flextension activities will either be included in the unit kit or are easily sourced. Supporting resources such as student worksheets will be included as downloadable PDF files.
Our kits include enough materials to support 200 student uses. In other words, teachers can easily support all five periods and small groups of 4–5 students each. Plus, our unit-specific kits mean teachers just grab the tub they need and then put all the materials back with ease.
Our digital Simulations and Practice Tools are powerful resources for exploration, data collection, and student collaboration. They allow students the ability to explore scientific concepts that might otherwise be invisible or impossible to see with the naked eye.
Available for every unit, our Student Investigation Notebooks contain instructions for activities and space for students to record data and observations, reflect on ideas from texts and investigations, and construct explanations and arguments.
In grades 6–8, one copy of the Student Investigation Notebook is included in each unit’s materials kit for use as a blackline master. Each notebook is also available as a downloadable PDF on the Unit Guide page of the digital Teacher’s Guide.
These customizable PowerPoints are available for every lesson of the program and make delivering instruction a snap with visual prompts, colorful activity instructions, investigation set-up videos and animations, and suggested teacher talk in the notes section of each slide.
Explore your print samples
With your Amplify Science Pennsylvania print samples, you’ll find unit-specific Teacher’s References Guides and Student Investigation Notebooks for each grade level.
A note about the Teacher Reference Guides:
It’s important that your committee sees the full breadth and depth of our instruction. For that reason, we’ve provided a copy of each of our unit-specific Teacher Reference Guides.
Teachers do not use these robust reference guides for day-to-day teaching. For that, we have a hands-free Teacher’s Guide!
- Teacher Reference Guide: Unlike a typical Teacher Guide that requires a series of supplemental books to support it, our encyclopedic reference guide is chock-full of everything a teacher needs to fully implement our program and the NGSS.
- Ready-to-Teach Lesson Slides: For daily instruction, teachers need their hands free. That’s why we created ready-to-teach lesson slides for every single lesson. What’s more, they are editable and include suggested teacher talk and point-of-use differentiation and other instructional tips. Click to learn more.
A note about the Materials Kits:
Hands-on learning is at the heart of Amplify Science Pennsylvania, and is integrated into every unit. In order to make hands-on learning more manageable for busy teachers, Amplify Science Pennsylvania materials are organized into unit-specific kits.
Our unit-specific kits:
- Include more materials. We give teachers enough materials to support 200 student uses.
- Are more manageable. Unlike other programs that require large groups of students to share limited sets of materials, our kits include enough to support small groups of four to five students.
- Include supportive videos. Each hands-on activity provides clear instructions for the teacher, with more complex activities supported by video demonstrations and illustrations.
Within each kit, we provide grade-specific lists of all materials included, which you can also find using the links below.
Spanish-language support
Amplify Science Pennsylvania is committed to providing support to meet the needs of all learners, including multiple access points for Spanish-speaking students. Developed in conjunction with Spanish-language experts and classroom teachers, several components are available in Spanish across the Amplify Science Pennsylvania curriculum.
Spanish-language materials include:
| COMPONENT | TEACHER/STUDENT |
| Student Investigation Notebooks | Student |
| Science articles | Student |
| Video transcripts | Student |
| Digital simulation translation keys | Student |
| Printed classroom materials Unit and chapter questions, key concepts, vocabulary cards, etc. |
Teacher |
| Copymasters | Teacher |
| Assessments | Teacher |
| Digital student experience license This license gives students access to the student resources in Spanish, including instructional text, articles, and assessments. Teachers can control student access to Spanish-language content through the digital Teacher’s Guide. |
Teacher |
| Spanish teacher support license This license includes teacher talk, projections, downloadable PDFs of all print resources, and video transcripts and closed captioning in Spanish. |
Teacher |
Resources to support your review
- Pennsylvania STEELS Standards Alignment
- Research Highlights
- Program Structure
- Phenomena
- Amplify Science & the 5E Model
- Approaches to Assessment
- Science & Literacy Integration
- Hands-on Investigations (Integrated-Specific Model)
- Hands-On Investigations (Discipline-Specific Model)
- Engineering in Amplify Science
Contact us
Support is always available. Our team is dedicated to helping you every step of the way.
Contact your dedicated Pennsylvania representative here.
Publisher presentation
The Lawrence Hall of Science
Developed by the science education experts at UC Berkeley’s Lawrence Hall of Science and the digital learning team at Amplify, our program features:
- A phenomena-based approach where students construct a complex understanding of each unit’s anchor phenomenon.
- A blend of cohesive storylines, hands-on investigations, rich discussions, literacy-rich activities, and digital tools.
- Carefully crafted units, chapters, lessons, and activities designed to deliver true 3-dimensional learning.
- An instructional design that supports all learners in accessing all standards.
Instructional model
The Amplify Science program is rooted in the proven, research-based pedagogy of Do, Talk, Read, Write, Visualize. Here’s how each element works:
DO
First-hand investigations are an important part of any science classroom, and Amplify Science has students getting hands-on in every unit—from building models of protein molecules to experimenting with electrical systems.
TALK
Student-to-student discourse and full-class discussions are an integral part of the program. Students are provided with numerous opportunities to engage in meaningful oral scientific argumentation, all while fostering a collaborative classroom environment.
READ
Students read scientific articles, focusing their reading activities on searching for evidence related to their investigation and, importantly, on asking and recording questions as they read through fascinating texts on 21st-century topics.
WRITE
Following real-world practices, students write scientific arguments based on evidence they’ve collected, making clear their reasoning about how a given piece of evidence connects to one of several claims.
VISUALIZE
By manipulating digital simulations and using modeling tools to craft visualizations of their thinking— just as real scientists and engineers do—students take their learning far beyond the confines of what they can physically see in the classroom in an exciting and authentic way.
Program structure
Our cyclical lesson design ensures students receive multiple exposures to concepts through a variety of modalities. As they progress through the lessons within a unit, students build and deepen their understanding, increasing their ability to develop and refine complex explanations of the unit’s phenomenon.
It’s this proven program structure and lesson design that enables Amplify Science to address 100% of the NGSS, and support students in mastering the Oregon Science Standards.
Unit types
While every unit delivers three-dimensional learning experiences and engages students in gathering evidence from a rich collection of sources, each unit also serves a unique instructional purpose.
In grades 6–8:
- One unit is a launch unit.
- Three units are core units.
- Two units are engineering internships.
Launch units are the first units taught in each year of Amplify Science. The goal of the Launch unit is to introduce students to norms, routines, and practices that will be built on throughout the year, including argumentation, active reading, and using the program’s technology. For example, rather than taking the time to explain the process of active reading in every unit in a given year, it is explained thoroughly in the Launch unit, thereby preparing students to read actively in all subsequent units.
Core units establish the context of the unit by introducing students to a real-world problem. As students move through lessons in a Core unit, they figure out the unit’s anchoring phenomenon, gain an understanding of the unit’s disciplinary core ideas and science and engineering practices, and make linkages across topics through the crosscutting concepts. Each Core unit culminates with a Science Seminar and final writing activity.
Engineering Internship units invite students to design solutions for real-world problems as interns for a fictional company called Futura. Students figure out how to help those in need, from tsunami victims in Sri Lanka to premature babies, through the application of engineering practices. In the process, they apply and deepen their learning from Core units.
Unit sequence
Our lessons follow a structure that is grounded in regular routines while still being flexible enough to allow for a variety of learning experiences.
In fact, our multi-modal instruction offers more opportunities for students to construct meaning, and practice and apply concepts than any other program. What’s more, our modular design means our units can be flexibly arranged to support your instructional goals.
Program components
Available digitally and in print, our unit-specific reference guides are chock full of helpful resources, including scientific background knowledge, planning information and resources, color-coded 3-D Statements, detailed lesson plans, tips for delivering instruction, and differentiation strategies.
Hands-on learning is an essential part of Amplify Science, and is integrated into every unit. Students actively participate in science, playing the roles of scientists and engineers as they gather evidence, think critically, solve problems, and develop and defend claims about the world around them. Every unit includes hands-on investigations that are critical to achieving the unit’s learning goals.
More hands-on with Flextensions:
Hands-on Flextensions are additional, optional investigations that are included at logical points in the learning progression and give students an opportunity to dig deeper if time permits. These activities offer teachers flexibility to choose to dedicate more time to hands-on learning. Materials referenced in Hands-on Flextension activities will either be included in the unit kit or are easily sourced. Supporting resources such as student worksheets will be included as downloadable PDF files.
Our kits include enough materials to support 200 student uses. In other words, teachers can easily support all five periods and small groups of 4-5 students each. Plus, our unit-specific kits mean teachers just grab the tub they need and then put it all back with ease.
Our digital Simulations and Practice Tools are powerful resources for exploration, data collection, and student collaboration. They allow students the ability to explore scientific concepts that might otherwise be invisible or impossible to see with the naked eye.
Available for every unit, our Student Investigation Notebooks contain instructions for activities and space for students to record data and observations, reflect on ideas from texts and investigations, and construct explanations and arguments.
In grades 6–8, one copy of the Student Investigation Notebook is included in each unit’s materials kit for use as a blackline master. Each notebook is also available as a downloadable PDF on the Unit Guide page of the digital Teacher’s Guide.
These customizable PowerPoints are available for every lesson of the program and make delivering instruction a snap with visual prompts, colorful activity instructions, investigation set-up videos and animations, and suggested teacher talk in the notes section of each slide.
Full coverage of the Oregon Science Standards
Amplify Science was designed from the ground up to meet the Next Generation Science Standards (NGSS). As such, it aligns to the Oregon Science Standards, which were also borne out of the NGSS.
The guidance below is meant to provide support for integrating additional activities that support full coverage of Oregon’s standards. Organized by grade level, each section below will outline:
- Additional activities that support 100% alignment to the Oregon Science Standards.
- The standard being addressed with the activities.
- The recommended placement of the activities within a specific Amplify Science unit.
- PDFs of any accompanying materials that are necessary to implement the activities.
Activity Title: Meet a Scientist Who Changed How We Think About Brain Cells
About this activity: In this activity, students read a short article about a scientist who studied the nervous system.
Recommended placement: Metabolism unit, Lesson 3.2
Materials:
Instructions: Download the PDF “Meet a Scientist Who Changed How We Think About Brain Cells” above and remind students of the Active Reading guidelines. Before students read the article, invite them to share prior experiences. Then have students complete the copymaster above.
Activity Title: Meet a Scientist Who Studies Underwater Currents
About this activity: In this activity, students read a short article about a scientist who studies ocean currents.
Recommended placement: Oceans, Atmosphere, and Climate unit, Lesson 2.1
Materials:
Instructions: Download the PDF “Meet a Scientist Who Studies Underwater Currents” above and remind students of the Active Reading guidelines. Before students read the article, invite them to share prior experiences. Then have students complete the copymaster above.
Activity Title: Meet a Scientist Who Studies How the Environment Affects Our Traits
About this activity: In this activity, students read two short articles, one about current research on genes and proteins, and one about a scientist who is studying how the environment can affect our traits.
Recommended placement: Traits and Reproduction unit, Lesson 2.4
Materials:
Instructions: Download the PDF “Meet a Scientist Who Studies How the Environment Affects Our Traits” above and remind students of the Active Reading guidelines. Before students read the article, invite them to share prior experiences. Then have students complete the copymaster above.
Activity Title: Who Becomes a Space Scientist?
About this activity: In this activity, Students read a short article about a scientist who studies space.
Recommended placement: Geology on Mars unit, Lesson 3.1
Materials:
Instructions: Download the PDF “Who Becomes a Space Scientist?” above and remind students of the Active Reading guidelines. Before students read the article, invite them to share prior experiences. Then have students complete the copymaster above.
Activity Title: Meet a Scientist Who Studies How Plants Find Water Underground
About this activity: In this activity, students read a short article about a scientist who studies how plants’ roots get water.
Recommended placement: Matter and Energy in Ecosystems unit, Lesson 1.6
Materials:
Instructions: Download the PDF “Meet a Scientist Who Studies How Plants Find Water Underground” above and remind students of the Active Reading guidelines. Before students read the article, invite them to share prior experiences. Then have students complete the copymaster above.
Activity Title: Bringing Back the Buffalo
About this activity: In this activity, students change one competing population to try to decrease the other in the Sim, and read a short article about a scientist who studies buffalo.
Recommended placement: Populations and Resources unit, Lesson 3.2
Materials:
Instructions: Download the PDF “Bringing Back the Buffalo” above and remind students of the Active Reading guidelines. Before students read the article, invite them to share prior experiences. Then have students complete the copymaster above.
Activity Title: Rereading “A Continental Puzzle”
About this activity: In this activity, students reread “A Continental Puzzle” and think about how patterns were helpful to Wegener’s work.
Recommended placement: Plate Motion unit, Lesson 3.2
Materials:
Instructions: Direct students back to “A Continental Puzzle” above and remind students of the Active Reading guidelines. Before students re-read the article, invite them to share prior experiences. Then have students complete the copymaster above.
Activity Title: Meet a Scientist Who Studies Variation in Monkey Populations
About this activity: In this activity, students read a short article about a scientist who studies variation of traits in monkey populations.
Recommended placement: Natural Selection unit, Lesson 1.6
Materials:
Instructions: Download the PDF “Meet a Scientist Who Studies Variation in Monkey Populations” above and remind students of the Active Reading guidelines. Before students read the article, invite them to share prior experiences. Then have students complete the copymaster above.
Activity Title: Extinctions and Human Impacts
About this activity: The purpose of this lesson is for students to see how increases in human population and consumption of natural resources can negatively impact Earth’s systems.
Recommended placement: Natural Selection unit, Lesson 4.5
Materials:
Instructions: Download the PDF “Extinctions and Human Impacts” above and remind students of the Active Reading guidelines. Before students read the article, invite them to share prior experiences. Then have students complete the copymaster above.
Activity Title: Steno and the Shark
About this activity: In this activity, students read a short article about Nicolas Steno, a scientist from the 1600s whose studies of fossilized sharks’ teeth embedded in rock layers laid the foundation for the modern understanding of stratigraphy.
Recommended placement: Evolutionary History unit, Lesson 2.4
Materials:
Instructions: Download the PDF “Steno and the Shark” above and remind students of the Active Reading guidelines. Before students read the article, invite them to share prior experiences. Then have students complete the copymaster above.
Activity Title: Scale in the Solar System
About this activity: In this activity, students read and annotate the articles “Scale in the Solar System” and “The Solar System Is Huge.”
Recommended placement: Earth, Moon, and Sun unit, Lesson 1.2
Materials:
Instructions: Download the PDF “Scale in the Solar System” above and remind students of the Active Reading guidelines. Before students read the article, invite them to share prior experiences. Then have students complete the copymaster above.
Explore your print samples
Amplify Science physical samples can be found at the Hamersley Library at Western Oregon University. There you’ll find unit-specific Teacher’s References Guides and Student Investigation Notebooks for each grade level.
A note about the Teacher’s Reference Guides:
It’s important that your committee sees the full breadth and depth of our instruction. For that reason, we provided a copy of each of our unit-specific Teacher Reference Guides.
Rest assured that teachers do not use these robust reference guides for day-to-day teaching. For that, we have a hands-free TG!
- Teacher Reference Guide: Unlike a typical TG that requires a series of supplemental books to support it, our encyclopedic reference guide is chock-full of everything a teacher needs to fully implement our program and the NGSS.
- Ready-to-Teach Lesson Slides: For daily instruction, teachers need their hands free. That’s why we created ready-to-teach lesson slides for every single lesson What’s more, they are editable and include suggested teacher talk and point-of-use differentiation and other instructional tips. Click to learn more.
A note about the Materials Kits:
Hands-on learning is at the heart of Amplify Science, and is integrated into every unit. In order to make hands-on learning more manageable for busy teachers, Amplify Science materials are organized into unit-specific kits.
Our unit-specific kits:
- Include more materials — We give teachers enough materials to support 200 student uses.
- Are more manageable — Unlike other programs that require large groups of students to share limited sets of materials, our kits include enough to support small groups of 4–5 students.
- Include supportive videos — Each hands-on activity provides clear instructions for the teacher, with more complex activities supported by video demonstrations and illustrations.
At your request, we did not include our materials kits with our submissions samples. However, we did provide grade-specific lists of all materials included in each kit, which you can also find with the links below.
Access your digital samples
Explore as a teacher
Follow these instructions to explore the Amplify Science digital platform as a teacher.
- Click the Access Amplify Science Platform button below.
- Select Log in with Amplify.
- Enter the teacher username and password found on your unique login flyer enclosed in your physical sample box.
- Click the Science icon.
- Click on the Grade Menu in the top center of the screen and select any grade.
- Select any unit.
To help familiarize yourself with navigating the digital platform, watch the below navigational video.
Explore as a student
Follow these instructions to explore the Amplify Science digital platform as a student.
- Click the Access Amplify Science Platform button below.
- Select Log in with Amplify.
- Enter the student username and password found on your unique login flyer enclosed in your physical sample box.
- Click the Science icon.
- Click on the Grade Menu in the top center of the screen and select any grade.
- Select any unit.
Resources to support your review
Oregon standards correlation for grades 6–8
QCD Science Adoption Criteria 2022 for grades 6-8
QCD IMET Citation guidance for grades 6-8
Oregon Science IMET for grades 6-8 (Excel download)
Oregon QCD-IMET Citation guidance for grades 6-8
Research behind Amplify Science
Program structure for grades 6–8
What is Boost Reading?
Boost Reading is a K–5 student-driven literacy program that provides both enrichment and remediation for all students, leveraging the power of compelling storytelling to engage students in personalized reading instruction and practice. It features:
- High quality, research-based instruction based on the science of reading
- Unparalleled personalized learning pathways
- Compelling and imaginative storylines
- Social and emotional learning
- Insightful reports tied to actionable next steps
How does Boost Reading work?
Boost Reading uses students’ latest reading assessment data to ensure they practice the right skills at the right time. In cases where no student assessment data is available, our embedded placement tool ensures students receive the content and skill practice most appropriate for their current reading level.
From there, students move through our curriculum along their own learning pathway where they encounter personalized content tailored to their evolving skill and grade levels.
Summary of games
With over 40 adaptive games, Boost Reading helps students of all levels grow across 13 critical skills areas, including explicit instruction in comprehension processes.
- Phonological awareness
- Letter sound correspondence
- Letter combinations
- Early decoding
- Advanced decoding
- Comprehension processes
- Key ideas and details
- Craft and structure
- Integration of knowledge and ideas
- Vocabulary
- Connected texts
- Fluency
- Close reading
See pages 16-78 of this guide for a detailed explanation of every game in the program.
How does Boost Reading integrate with the other parts of the literacy system?
Boost Reading + mCLASS® with DIBELS® 8th Edition
mCLASS automatically places students on an adaptive path within Boost Reading, which provides them the exact practice–both remediation and acceleration–that they need.
Click here to learn more about how Boost Reading and the mCLASS Assessment System work together.
Boost Reading + Amplify CKLA
Boost Reading extends core instruction with Amplify CKLA with personalized practice that follows the same scope and sequence.
Click here to learn more about how Boost Reading and Amplify CKLA work together.
What makes Boost Reading different?
Multiple dimensions
Boost Reading features full adaptivity. That means students progress along a pathway that adapts on multiple dimensions, not just one. For example, a student can work on early first-grade decoding in one game while building more advanced vocabulary knowledge in another.
Always-positive feedback
Boost Reading supports positive participation by giving students immediate and clear feedback. These results are never punitive. Instead our always-positive feedback is delivered in the context of the game world and is designed to motivate students to keep trying.
Focus on SEL
Sustained academic success depends upon social and emotional learning (SEL) as well as the mastery of fundamental literacy skills. Consistent with the most widely-recognized framework and standards for SEL (from the CASEL consortium, which includes 25 states), Boost Reading also focuses on the five areas of social and emotional learning:
- Self-awareness
- Self-management
- Social awareness
- Relationship skills
- Responsible decision-making
Ready-to-teach mini-lessons
Boost Reading turns data into action with reports that help educators know exactly who needs support and ready-to-teach mini-lessons that deliver targeted reinforcement and remediation.
Accelerated growth
Boost Reading accelerates student growth at all reading levels and reduces the number of students at risk of reading difficulty. In one study of 3rd graders in a large urban district who used Boost Reading for only one semester:
- 54% of students who used Boost Reading made above average progress, whereas only 44% of students in the comparison group made above average progress.
- 54% of English learners in that same study made above average growth, whereas only 45% of English learners in the comparison group made above average growth.
Check out the above results and more in this efficacy paper.
Demo access
Follow the instructions below to login to your demo account.
- Click the Boost Reading Demo button below.
- Select Log in with Amplify.
- Enter the username: atahan
- Enter the password: Abcd1234
- Click the mCLASS®: Boost Reading Edition tile.
Check out these additional resources
Boost Reading review resources:
What is Boost Reading?
Boost Reading is a K–5 student-driven literacy program that provides both enrichment and remediation for all students, leveraging the power of compelling storytelling to engage students in personalized reading instruction and practice. It features:
- High quality, research-based instruction based on the Science of Reading.
- Unparalleled personalized learning pathways.
- Compelling and imaginative storylines.
- Social and emotional learning.
- Insightful reports tied to actionable next steps.
How does Boost Reading work?
Boost Reading uses students’ latest reading assessment data to ensure they practice the right skills at the right time. In cases where no student assessment data is available, our embedded placement tool ensures students receive the content and skill practice most appropriate for their current reading level.
From there, students move through our curriculum along their own learning pathway where they encounter personalized content tailored to their evolving skill and grade levels.
Summary of games
With over 40 adaptive games, Boost Reading helps students of all levels grow across 13 critical skills areas, including explicit instruction in comprehension processes.
- Phonological awareness
- Letter sound correspondence
- Letter combinations
- Early decoding
- Advanced decoding
- Comprehension processes
- Key ideas and details
- Craft and structure
- Integration of knowledge and ideas
- Vocabulary
- Connected texts
- Fluency
- Close reading
See pages 16-78 of this guide for a detailed explanation of every game in the program.
What makes Boost Reading different?
Multiple dimensions
Boost Reading features full adaptivity. That means students progress along a pathway that adapts on multiple dimensions, not just one. For example, a student can work on early first-grade decoding in one game while building more advanced vocabulary knowledge in another.
Always-positive feedback
Boost Reading supports positive participation by giving students immediate and clear feedback. These results are never punitive. Instead our always-positive feedback is delivered in the context of the game world and is designed to motivate students to keep trying.
Focus on SEL
Sustained academic success depends upon social and emotional learning (SEL) as well as the mastery of fundamental literacy skills. Consistent with the most widely-recognized framework and standards for SEL (from the CASEL consortium, which includes 25 states), Boost Reading also focuses on the five areas of social and emotional learning:
- Self-awareness
- Self-management
- Social awareness
- Relationship skills
- Responsible decision-making
Ready-to-teach mini-lessons
Boost Reading turns data into action with reports that help educators know exactly who needs support and ready-to-teach mini-lessons that deliver targeted reinforcement and remediation.
Accelerated growth
Boost Reading accelerates student growth at all reading levels and reduces the number of students at risk of reading difficulty. In one study of 3rd graders in a large urban district who used Boost Reading for only one semester:
- 54% of students who used Boost Reading made above average progress, whereas only 44% of students in the comparison group made above average progress.
- 54% of English learners in that same study made above average growth, whereas only 45% of English learners in the comparison group made above average growth.
Check out the above results and more in this efficacy paper.
How does Boost Reading integrate with the other parts of the literacy system?
Boost Reading + mCLASS® with DIBELS® 8th Edition
mCLASS automatically places students on an adaptive path within Boost Reading, which provides them the exact practice–both remediation and acceleration–that they need.
Click here to learn more about how Boost Reading and the mCLASS Assessment System work together.
Boost Reading + Amplify CKLA
Boost Reading extends core instruction with Amplify CKLA with personalized practice that follows the same scope and sequence.
Click here to learn more about how Boost Reading and Amplify CKLA work together.
Check out these additional resources
Boost Reading review resources:
What is Boost Reading?
Boost Reading is a K–5 student-driven literacy program that provides both enrichment and remediation for all students, leveraging the power of compelling storytelling to engage students in personalized reading instruction and practice. It features:
- High quality, research-based instruction based on the Science of Reading.
- Unparalleled personalized learning pathways.
- Compelling and imaginative storylines.
- Social and emotional learning.
- Insightful reports tied to actionable next steps.
How does Boost Reading work?
Boost Reading uses students’ latest reading assessment data to ensure they practice the right skills at the right time. In cases where no student assessment data is available, our embedded placement tool ensures students receive the content and skill practice most appropriate for their current reading level.
From there, students move through our curriculum along their own learning pathway where they encounter personalized content tailored to their evolving skill and grade levels.
Summary of games
With over 40 adaptive games, Boost Reading helps students of all levels grow across 13 critical skills areas, including explicit instruction in comprehension processes.
- Phonological awareness
- Letter sound correspondence
- Letter combinations
- Early decoding
- Advanced decoding
- Comprehension processes
- Key ideas and details
- Craft and structure
- Integration of knowledge and ideas
- Vocabulary
- Connected texts
- Fluency
- Close reading
See pages 16-78 of this guide for a detailed explanation of every game in the program.
What makes Boost Reading different?
Multiple dimensions
Boost Reading features full adaptivity. That means students progress along a pathway that adapts on multiple dimensions, not just one. For example, a student can work on early first-grade decoding in one game while building more advanced vocabulary knowledge in another.
Always-positive feedback
Boost Reading supports positive participation by giving students immediate and clear feedback. These results are never punitive. Instead our always-positive feedback is delivered in the context of the game world and is designed to motivate students to keep trying.
Focus on SEL
Sustained academic success depends upon social and emotional learning (SEL) as well as the mastery of fundamental literacy skills. Consistent with the most widely-recognized framework and standards for SEL (from the CASEL consortium, which includes 25 states), Boost Reading also focuses on the five areas of social and emotional learning:
- Self-awareness
- Self-management
- Social awareness
- Relationship skills
- Responsible decision-making
Ready-to-teach mini-lessons
Boost Reading turns data into action with reports that help educators know exactly who needs support and ready-to-teach mini-lessons that deliver targeted reinforcement and remediation.
Accelerated growth
Boost Reading accelerates student growth at all reading levels and reduces the number of students at risk of reading difficulty. In one study of 3rd graders in a large urban district who used Boost Reading for only one semester:
- 54% of students who used Boost Reading made above average progress, whereas only 44% of students in the comparison group made above average progress.
- 54% of English learners in that same study made above average growth, whereas only 45% of English learners in the comparison group made above average growth.
Check out the above results and more in this efficacy paper.
How does Boost Reading integrate with the other parts of the literacy system?
Boost Reading + mCLASS® with DIBELS® 8th Edition
mCLASS automatically places students on an adaptive path within Boost Reading, which provides them the exact practice–both remediation and acceleration–that they need.
Click here to learn more about how Boost Reading and the mCLASS Assessment System work together.
Boost Reading + Amplify CKLA
Boost Reading extends core instruction with Amplify CKLA with personalized practice that follows the same scope and sequence.
Click here to learn more about how Boost Reading and Amplify CKLA work together.
Demo access
Follow the instructions below to login to your demo account.
- Click the Boost Reading Demo button below.
- Select Log in with Amplify.
- Enter the username: atahan
- Enter the password: Abcd1234
- Click the mCLASS®: Boost Reading Edition tile.
Check out these additional resources
Boost Reading review resources:
About the program
mCLASS offers teacher-administered assessment, intervention, and personalized instruction for grades K–6. Know exactly how to monitor and support every student in your classroom, with features like:
- Precise one-minute measures based on over three decades of predictive data.
- Universal and Reading Difficulties screening in one tool.
- Instruction that highlights observed patterns and recommends activities.
- Robust reports for teachers, specialists, administrators, and parents.
The right measures at the right time
With mCLASS DIBELS 8th Edition, you’ll assess students based on grade-specific curriculum and instructional standards, in accordance with International Dyslexia Association (IDA) guidelines.
mCLASS DIBELS 8th Edition offers one-minute, easy-to-administer measures of processing speed, phonological awareness, alphabetic principle, and word reading.
| DIBELS® 8th Edition subtest alignment with SB 114 requirements | ||||||
|---|---|---|---|---|---|---|
| RDRP Screening Area | mCLASS DIBELS 8th Edition Measure | Grade K | Grade 1 | Grade 2 | Grade 3 | Grade 4–6 |
| Rapid naming ability | Letter Naming Fluency (LNF) | | | |||
| Phonological awareness | Phoneme Segmentation Fluency (PSF) | | | |||
| Alphabetic principle | Nonsense Word Fluency (NWF) | | | | | |
| Word reading | Word Reading Fluency (WRF) | | | | | |
| Word reading | Oral Reading Fluency (ORF) | | | | | |
| Comprehension | Maze | | | | ||
| Language Comprehension | Oral Language | | | | ||
| Vocabulary | Vocabulary | | | | | |
| RAN | Rapid Automatized Naming (Numbers) | | | | | |
| Encoding | Spelling | OPTIONAL | ||||
Validated as a universal screener and a dyslexia screener
Strong reliability and validity evidence shows that DIBELS 8th Edition can effectively assess students in key skills linked to both dyslexia and broader reading difficulty. The research supporting DIBELS 8th Edition, conducted by the University of Oregon, is rigorous, meets high technical standards, and empowers educators to make well-informed decisions.
Read the DIBELS 8th Edition Dyslexia White Paper.
A complete system for data-based decision making
mCLASS DIBELS 8th Edition provides rich data that helps you make informed instructional decisions and seek out further dyslexia screening evaluation if needed:
- Assess skills: mCLASS DIBELS 8th Edition and optional dyslexia screenings in Rapid Automatized Naming (RAN), Spelling, Vocabulary, and Oral Language accurately assess students’ abilities.
- Identify risk: The DIBELS 8 composite score shows each student’s risk level, with ‘Well Below Benchmark’ indicating a need for intensive support. Students who are also ‘Well Below Benchmark’ in RAN and/or Spelling have an additional Risk Indicator icon next to their name.
- Provide instruction: The mCLASS Instruction feature analyzes student error patterns to key dyslexia-related subtests, then recommends small groups and explicit, multi-sensory activities for reinforcing skills.
- Progress monitor: mCLASS includes progress-monitoring measures to track student growth in letter sounds, alphabetic principle, word reading, oral reading fluency, and comprehension, so that informed instructional decisions can be made.
- Adapt instruction: mCLASS displays indicators based on progress monitoring performance that indicate when a change in instruction may be needed. It also updates instruction recommendations using the latest data.
Differentiated literacy instruction
mCLASS DIBELS 8th Edition lays the groundwork for a strong Multi-Tiered System of Supports (MTSS).
In addition to identifying students with symptoms of dyslexia, mCLASS DIBELS 8th Edition data recommends early intervention, personalized instruction, and core instruction within Amplify’s early literacy suite. Based on the Science of Reading, Amplify’s early literacy suite programs follow an explicit and systematic structure, build knowledge, and instruct on all of the foundational skills essential to literacy development.
- Intervene with mCLASS Intervention and Amplify Tutoring: Staff-led Tier 2 and 3 intervention for intensive support.
- Practice with Boost Reading: Personalized learning program to extend and reinforce core instruction.
- Instruct with Amplify Core Knowledge Language Arts (CKLA): Core curriculum to build foundational skills and knowledge.
Bilingual Reading Difficulties screening
By assessing with mCLASS DIBELS 8th Edition and its Spanish counterpart, mCLASS Lectura, you’ll know with confidence whether a student truly shows signs of of reading difficulties or is experiencing difficulties learning a new language.
When used together, mCLASS DIBELS 8th Edition and mCLASS Lectura feature a Dual Language Report that analyzes Reading Difficulties screening results in both languages. The report also details how each student can leverage their strengths from one language to support growth in the other.
Equal skill coverage in English and Spanish
mCLASS Lectura subtest alignment with SB114
| RDRP screening areas | English measure | Spanish measure | Description* |
|---|---|---|---|
| Letter Naming and RAN | Letter Naming Fluency (LNF) | Fluidez in nombrar letras (FNL) | Grades K–1: Naming letters in print. 1 minute, 1:1 administration. |
| Phonological Awareness (Segmentation) | Phonemic Segmentation Fluency (PSF) | Fluidez en la segmentación de sílabas (FSS) & Fluidez en la segmentación de fonemas (FSF) | Grades K–1: Hearing and using sounds or syllables in spoken words. 1 minute, 1:1 administration. |
| Phonological Awareness (Elision) | – | ¿Qué queda? (QQ) | Grades K–2: Produce the part of a word that remains after deleting a syllable or phoneme. 1 minute, 1:1 administration. |
| Letter Sound Correspondence Knowledge | Nonsense Word Fluency Correct Letter Sounds(NWF-CLS) | Fluidez en los sonidos de letras (FSL) | English: Grades K–3: Identify letter-sound correspondences in the context of pseudo-words. Spanish: Grades K-1: Identify letter-sounds in isolation. 1 minute, 1:1 administration. |
| Letter-Sound Knowledge (Receptive) | – | Fluidez en los sonidos de las letras K-Inicio (FSL K-Inicio) | Grade K: Identify (point to) which letter makes a certain sound. Untimed, 1:1 administration. |
| Decoding | Nonsense Word Fluency Words Recoded Correctly (NWF-WRC) | Fluidez en los sonidos de las sílabas (FSL) | Grades K–3: Identify letter-sound correspondences in the context of pseudo-words. Spanish: Grades K–1: Identify letter-sounds in isolation. 1 minute, 1:1 administration. |
| Word Reading | Word-Reading Fluency (WRF) | Fluidez en las palabras (FEP) | Grades K–3: Reading common words easily, quickly and correctly.1 minute, 1:1 administration. |
| Fluency | Oral Reading Fluency (ORF) | Fluidez en la lectura oral (FLO) | Grades 1–6: Reading connected text with accuracy and automaticity. 1 minute, 1:1 administration. |
| Reading Comprehension | Maze | ¿Cuál palabra? (CP) | Grades 2–6: Understanding meaning from texts. 3 minutes, group administration. |
| Vocabulary | Vocabulary | Vocabulario | Grades K–3: Arranging letters correctly to spell words with grade appropriate features. 15 minutes, group administration. |
| Encoding | Spelling | Ortografía | Grades K–3: Arranging letters correctly to spell words with grade-appropriate features. 15 minutes, group administration. |
| RAN (Numbers) | Rapid Automatized Naming | – | Grades K–3: Correctly and quickly naming visual symbols, such as numbers. 1-2 minutes, 1:1 administration. |
| Language Comprehension | Oral Language | Lenguaje oral | Grades K–2: Demonstrate the ability to use words and phrases acquired through conversations, reading and being read to, and responding to texts. 5 minutes, 1:1 administration. |
*Students can be assessed using off-grade measures when information on specific skills is needed.
Resources for families
Welcome California Caregivers! Please click here to learn more about mCLASS assessments.
Families play a crucial role in helping children overcome reading challenges. mCLASS DIBELS 8th Edition and mCLASS Lectura provide a Home Connect letter after each screening to explain the results in family-friendly language, recommend activities, and direct families to a free website for additional at-home support.
Developmentally appropriate
Computer-based assessments that require students to complete tasks silently or independently may over-identify students for intervention services, especially young learners who are still developing focus and attention abilities.
mCLASS requires students to actively demonstrate their proficiency in producing letter sounds, forming words, and reading texts. This approach to assessment aligns with IDA guidelines for effective screening of reading challenges. By choosing mCLASS for universal screening, you’ll gain accurate information about a student’s risk for reading difficulties, and gain the capability to monitor every student’s path to reading proficiency.
Additional resources
mCLASS Resources
- mCLASS Research Hub
- mCLASS Program Guide
- mCLASS Digital Access Guide
- mCLASS Reporting Guide
- mCLASS Help Site
- mCLASS self-guided walkthrough
Dyslexia Resources
- mCLASS Dyslexia Toolkit
- Dyslexia Fact vs. Fiction ebook
- Blog post: 4 tools to help teachers better understand dyslexia
- Science of Reading: The Podcast, Season 7, Episode 7: Debunking the “gift” of dyslexia in children, with Dr. Tim Odegard
- Science of Reading: The Podcast, Season 1, Episode 6: The facts and myths of dyslexia, with Emily Lutrick
Multilingual and English learners Resources
Your California team
Looking to speak directly with your local representative?
Get in touch with a California team member to learn more about our early literacy suite or request a demo account.
Dan Pier
Vice President, West
(415) 203-4810
dpier@amplify.com
Erin King
Sales Director, CA
(512) 736-3162
eking@amplify.com
NORTHERN CA
Wendy Garcia
Senior Account Executive
(510) 368-7666
wgarcia@amplify.com
BAY AREA
Lance Burbank
Account Executive
(415) 830-5348
lburbank@amplify.com
CENTRAL VALLEY and CENTRAL COAST
Demitri Gonos
Senior Account Executive
(559) 355-3244
dgonos@amplify.com
VENTURA and L.A. COUNTY
Jeff Sorenson
Associate Account Executive
(310) 902-1407
jsorenson@amplify.com
ORANGE and L.A. COUNTY
Lauren Sherman
Senior Account Executive
(949) 397-5766
lsherman@amplify.com
SAN BERNARDINO and L.A. COUNTY
Michael Gruber
Senior Account Executive
(951) 520-6542
migruber@amplify.com
RIVERSIDE AND L.A. COUNTY
Brian Roy
Senior Account Executive
(818)967-1674
broy@amplify.com
SAN DIEGO COUNTY
Kirk Van Wagoner
Senior Account Executive
(760) 696-0709
kvanwagoner@amplify.com
BUTTE, DEL NORTE, HUMBOLDT, and SHASTA COUNTY and DISTRICTS UNDER 2250 ENROLLMENT
Kevin Mauser
Lead Account Executive
(815) 534-0148
kmauser@amplify.com
What is Amplify Science?
The Lawrence Hall of Science
Developed by the science education experts at UC Berkeley’s Lawrence Hall of Science and the digital learning team at Amplify, our program features:
- A phenomena-based approach where students construct a complex understanding of each unit’s anchor phenomenon.
- A blend of cohesive storylines, hands-on investigations, rich discussions, literacy-rich activities, and digital tools.
- Carefully crafted units, chapters, lessons, and activities designed to deliver true 3-dimensional learning.
- An instructional design that supports all learners in accessing all standards.
Proven to work
Instructional model
The Amplify Science program is rooted in the proven, research-based pedagogy of Do, Talk, Read, Write, Visualize. Here’s how each element works:
Do
First-hand investigations are an important part of any science classroom, and Amplify Science has students getting hands-on in every unit—from building models of protein molecules to experimenting with electrical systems.
Talk
Student-to-student discourse and full-class discussions are an integral part of the program. Students are provided with numerous opportunities to engage in meaningful oral scientific argumentation, all while fostering a collaborative classroom environment.
Read
Students read scientific articles, focusing their reading activities on searching for evidence related to their investigation and, importantly, on asking and recording questions as they read through fascinating texts on 21st-century topics.
Write
Following real-world practices, students write scientific arguments based on evidence they’ve collected, making clear their reasoning about how a given piece of evidence connects to one of several claims.
Visualize
By manipulating digital simulations and using modeling tools to craft visualizations of their thinking— just as real scientists and engineers do—students take their learning far beyond the confines of what they can physically see in the classroom in an exciting and authentic way.
Program structure
Our cyclical lesson design ensures students receive multiple exposures to concepts through a variety of modalities. As they progress through the lessons within a unit, students build and deepen their understanding, increasing their ability to develop and refine complex explanations of the unit’s phenomenon.
It’s this proven program structure and lesson design that enables Amplify Science to address 100% of the NGSS, and support students in mastering the Utah Science Standards.
Unit types
While every unit delivers three-dimensional learning experiences and engages students in gathering evidence from a rich collection of sources, each unit also serves a unique instructional purpose.
In grades 6–8:
- One unit is a launch unit.
- Three units are core units.
- Two units are engineering internships.
Launch units are the first units taught in each year of Amplify Science. The goal of the Launch unit is to introduce students to norms, routines, and practices that will be built on throughout the year, including argumentation, active reading, and using the program’s technology. For example, rather than taking the time to explain the process of active reading in every unit in a given year, it is explained thoroughly in the Launch unit, thereby preparing students to read actively in all subsequent units.
Core units establish the context of the unit by introducing students to a real-world problem. As students move through lessons in a Core unit, they figure out the unit’s anchoring phenomenon, gain an understanding of the unit’s disciplinary core ideas and science and engineering practices, and make linkages across topics through the crosscutting concepts. Each Core unit culminates with a Science Seminar and final writing activity.
Engineering Internship units invite students to design solutions for real-world problems as interns for a fictional company called Futura. Students figure out how to help those in need, from tsunami victims in Sri Lanka to premature babies, through the application of engineering practices. In the process, they apply and deepen their learning from Core units.
Unit sequence
Our lessons follow a structure that is grounded in regular routines while still being flexible enough to allow for a variety of learning experiences.
In fact, our multi-modal instruction offers more opportunities for students to construct meaning, and practice and apply concepts than any other program. What’s more, our modular design means our units can be flexibly arranged to support your instructional goals.
Program components
Available digitally and in print, our unit-specific reference guides are chock full of helpful resources, including scientific background knowledge, planning information and resources, color-coded 3D Statements, detailed lesson plans, tips for delivering instruction, and differentiation strategies.
Hands-on learning is an essential part of Amplify Science, and is integrated into every unit. Students actively participate in science, playing the roles of scientists and engineers as they gather evidence, think critically, solve problems, and develop and defend claims about the world around them. Every unit includes hands-on investigations that are critical to achieving the unit’s learning goals.
More hands-on with Flextensions:
Hands-on Flextensions are additional, optional investigations that are included at logical points in the learning progression and give students an opportunity to dig deeper if time permits. These activities offer teachers flexibility to choose to dedicate more time to hands-on learning. Materials referenced in Hands-on Flextension activities will either be included in the unit kit or are easily sourced. Supporting resources such as student worksheets will be included as downloadable PDF files.
Our kits include enough materials to support 200 student uses. In other words, teachers can easily support all five periods and small groups of 4-5 students each. Plus, our unit-specific kits mean teachers just grab the tub they need and then put it all back with ease.
Our digital Simulations and Practice Tools are powerful resources for exploration, data collection, and student collaboration. They allow students the ability to explore scientific concepts that might otherwise be invisible or impossible to see with the naked eye.
Available for every unit, our Student Investigation Notebooks contain instructions for activities and space for students to record data and observations, reflect on ideas from texts and investigations, and construct explanations and arguments.
In grades 6–8, one copy of the Student Investigation Notebook is included in each unit’s materials kit for use as a blackline master. Each notebook is also available as a downloadable PDF on the Unit Guide page of the digital Teacher’s Guide.
These customizable PowerPoints are available for every lesson of the program and make delivering instruction a snap with visual prompts, colorful activity instructions, investigation set-up videos and animations, and suggested teacher talk in the notes section of each slide.
Explore your print samples
With your Amplify Science print samples, you’ll find unit-specific Teacher’s References Guides and Student Investigation Notebooks for each grade level.
A note about the Teacher’s Reference Guides:
It’s important that your committee sees the full breadth and depth of our instruction. For that reason, we provided a copy of each of our unit-specific Teacher Reference Guides.
Rest assured that teachers do not use these robust reference guides for day-to-day teaching. For that, we have a hands-free TG!
- Teacher Reference Guide: Unlike a typical TG that requires a series of supplemental books to support it, our encyclopedic reference guide is chock-full of everything a teacher needs to fully implement our program and the NGSS.
- Ready-to-Teach Lesson Slides: For daily instruction, teachers need their hands free. That’s why we created ready-to-teach lesson slides for every single lesson. What’s more, they are editable and include suggested teacher talk and point-of-use differentiation and other instructional tips. Click to learn more.
A note about the Materials Kits:
Hands-on learning is at the heart of Amplify Science, and is integrated into every unit. In order to make hands-on learning more manageable for busy teachers, Amplify Science materials are organized into unit-specific kits.
Our unit-specific kits:
- Include more materials — We give teachers enough materials to support 200 student uses.
- Are more manageable — Unlike other programs that require large groups of students to share limited sets of materials, our kits include enough to support small groups of 4–5 students.
- Include supportive videos — Each hands-on activity provides clear instructions for the teacher, with more complex activities supported by video demonstrations and illustrations.
At your request, we did not include our materials kits with our submissions samples. However, we did provide grade-specific lists of all materials included in each kit, which you can also find with the links below.
Access your digital samples
Explore as a teacher
Follow these instructions to explore the Amplify Science digital platform as a teacher.
- Click the Access Amplify Science Platform button below and bookmark it.
- Select Log in with Amplify.
- Enter the username: t.msscienceut@tryamplify.net
- Enter the password: AmplifyNumber1
- Click the Science icon.
- Click on the Grade Menu in the top center of the screen and select any grade.
- Select any unit.
To help familiarize yourself with navigating the digital platform, watch the below navigational video.
Explore as a student
Follow these instructions to explore the Amplify Science digital platform as a student.
- Click the Access Amplify Science Platform button below and bookmark it.
- Select Log in with Amplify.
- Enter the username: s.msscienceut@tryamplify.net
- Enter the password: AmplifyNumber1
- Click the Science icon.
- Click on the Grade Menu in the top center of the screen and select any grade.
- Select any unit.
Resources to support your review
- Utah K-8 High Quality Instructional Materials (HQIM) Review Rubric
- K-8 Standards Alignment to Utah SEEd Standards
- Research behind Amplify Science
- Phenomena in grades 6–8
- Program structure for grades 6–8
- Active Reading in grades 6–8
- Engineering in Amplify Science
- Approaches to assessment in grades 6–8
- Amplify Technical Requirements
What is Boost Reading?
Boost Reading is a K–5 student-driven literacy program that provides both enrichment and remediation for all students, leveraging the power of compelling storytelling to engage students in personalized reading instruction and practice. It features:
- High quality, research-based instruction based on the Science of Reading.
- Unparalleled personalized learning pathways.
- Compelling and imaginative storylines.
- Insightful reports tied to actionable next steps.
How does Boost Reading work?
Boost Reading uses students’ latest reading assessment data to ensure they practice the right skills at the right time. In cases where no student assessment data is available, our embedded placement tool ensures students receive the content and skill practice most appropriate for their current reading level.
From there, students move through our curriculum along their own learning pathway where they encounter personalized content tailored to their evolving skill and grade levels.
Summary of games
With over 40 adaptive games, Boost Reading helps students of all levels grow across 13 critical skills areas, including explicit instruction in comprehension processes.
- Phonological awareness
- Letter sound correspondence
- Letter combinations
- Early decoding
- Advanced decoding
- Comprehension processes
- Key ideas and details
- Craft and structure
- Integration of knowledge and ideas
- Vocabulary
- Connected texts
- Fluency
- Close reading
See pages 16-78 of this guide for a detailed explanation of every game in the program.
What makes Boost Reading different?
Multiple dimensions
Boost Reading features full adaptivity. That means students progress along a pathway that adapts on multiple dimensions, not just one. For example, a student can work on early first-grade decoding in one game while building more advanced vocabulary knowledge in another.
Always-positive feedback
Boost Reading supports positive participation by giving students immediate and clear feedback. These results are never punitive. Instead our always-positive feedback is delivered in the context of the game world and is designed to motivate students to keep trying.
Ready-to-teach mini-lessons
Boost Reading turns data into action with reports that help educators know exactly who needs support and ready-to-teach mini-lessons that deliver targeted reinforcement and remediation.
Accelerated growth
Boost Reading accelerates student growth at all reading levels and reduces the number of students at risk of reading difficulty. In one study of 3rd graders in a large urban district who used Boost Reading for only one semester:
- 54% of students who used Boost Reading made above average progress, whereas only 44% of students in the comparison group made above average progress.
- 54% of English learners in that same study made above average growth, whereas only 45% of English learners in the comparison group made above average growth.
Check out the above results and more in this efficacy paper.
How does Boost Reading integrate with the other parts of the literacy system?
Boost Reading + mCLASS® with DIBELS® 8th Edition
mCLASS automatically places students on an adaptive path within Boost Reading, which provides them the exact practice–both remediation and acceleration–that they need.
Click here to learn more about how Boost Reading and the mCLASS Assessment System work together.
Boost Reading + Amplify CKLA
Boost Reading extends core instruction with Amplify CKLA with personalized practice that follows the same scope and sequence.
Click here to learn more about how Boost Reading and Amplify CKLA work together.
Demo access
Follow the instructions below to login to your demo account.
- Click the Boost Reading Demo button below.
- Select Log in with Amplify.
- Enter the username: atahan
- Enter the password: Abcd1234
- Click the mCLASS®: Boost Reading Edition tile.
- Follow the instructions on pages 5 and 6 of this document.
Check out these additional resources
Boost Reading review resources:
Welcome, Massachusetts reviewers!
On this site, you will find the following information to assist you as you review Amplify Core Knowledge Language Arts: a program overview to get you started, the CKLA knowledge sequence, comprehensive program guides for a deeper dive into the research base and day-to-day instruction, and other useful information. You’ll also find a month’s worth of lessons for each grade level.
CKLA was developed by the Core Knowledge Foundation and Amplify.
Getting started
Welcome to CKLA, a comprehensive reading and language arts curriculum built on today’s rigorous standards. CKLA delivers superior results through a uniquely research-based approach, combining step-by-step foundational skills with meaningful content knowledge in science, history, literature, and the arts. By focusing deeply on building students’ knowledge base, CKLA levels the playing field for every child.
Read the program overview to learn more about CKLA’s unique approach.
Grades K–2
In grades K–2, Amplify CKLA is segmented into two distinct strands: Knowledge and Skills.
Skills Strand: Skills Strand lessons build a strong foundation for students through daily instruction in phonemic awareness, spelling patterns, decoding with engaging, decodable texts, writing mechanics, and writing structure and processes.
Knowledge Strand It is vital to build students’ knowledge and vocabulary while they are still in the process of learning to read. In doing so, you better ensure their long-term success. CKLA’s Knowledge Strand is based on that very principle.
Grades K–2 Resources
K–2 materials
Core components for grades K–2:
Teacher Guide
You’ll find step-by-step lessons that are comprehensive, engaging, and support every learner.
Activity Book
With an integrated approach to reading and writing, students practice new sound-spellings by reading them in diverse contexts and then writing in response to the text.
Reader
Unlike other decodable texts, CKLA’s Readers feature engaging plots and characters, making the process of learning to read rewarding.
Grades 3–5
In grades 3–5, the Skills and Knowledge strands are integrated. As part of the curriculum’s research-based design, students in grades 3–5 spend several weeks immersed in sequenced domains in science, history, and literature, deepening both critical literacy skills and background knowledge.
Grades 3–5 Resources
Grades 3–5 materials
Core components for grades 3–5:
Teacher Guide
Teacher Guides for each unit provide step-by-step guidance, clear lesson objectives, and formative assessment as well as differentiated supports to empower teachers with proven strategies and research-based tools.
Activity Book
Anchored by the unit’s text, Activity Books immerse students in content-rich learning for deeper comprehension. They provide daily opportunities for students to respond to text while applying knowledge and serve as formative assessments connected to each day’s objectives.
Reader
Rich in knowledge and diverse in content, Student Readers are the foundation of each unit as students dive into increasingly complex text and sharpen their analytical skills. From geology to the Middle Ages, students engage with a truly diverse range of topics.
Welcome, Volusia reviewers!
Welcome to Amplify Core Knowledge Language Arts (CKLA), a comprehensive reading and language arts curriculum for Grades K–5 built on today’s rigorous standards. Amplify CKLA delivers superior results through a uniquely research-based approach, combining explicit foundational skills instruction with meaningful content knowledge in science, history, literature, and the arts.
By focusing deeply on building students’ knowledge base, Amplify CKLA levels the playing field for every child.
Amplify CKLA was developed by the Core Knowledge Foundation and Amplify.
Grades K–2 introduction
In grades K–2, Amplify CKLA is segmented into two distinct strands: Knowledge and Skills.
Skills Strand: Skills Strand lessons build a strong foundation for students through daily instruction in phonemic awareness, spelling patterns, decoding with engaging, decodable texts, writing mechanics, and writing structure and processes.
Knowledge Strand: It is vital to build students’ knowledge and vocabulary while they are still in the process of learning to read. In doing so, you better ensure their long-term success. CKLA’s Knowledge Strand is based on that very principle.
Grades K–2 materials
Student Reader
Unlike other decodable texts, CKLA’s Readers feature engaging plots and characters, making the process of learning to read rewarding. Student Readers are provided for each unit in the program beginning in Kindergarten Unit 6.
Grades 3–5 introduction
In grades 3–5, the Skills and Knowledge strands are integrated. As part of the curriculum’s research-based design, students in grades 3–5 spend several weeks immersed in sequenced domains in science, history, and literature, deepening both critical literacy skills and background knowledge.
Grades 3–5 materials
Student Reader
Rich in knowledge and diverse in content, Student Readers are the foundation of each unit as students dive into increasingly complex text and sharpen their analytical skills. From geology to the Middle Ages, students engage with a truly diverse range of topics.
Student Readers
- Unit 1: Classic Tales: The Wind in the Willows
- Unit 2: Animal Classification
- Unit 3: The Human Body
- Unit 4: The Ancient Roman Civilization
- Unit 5: Light and Sound
- Unit 6: The Viking Age
- Unit 7: Astronomy: Our Solar System and Beyond
- Unit 8: Native Americans: Regions and Cultures
- Unit 9: Early Explorations of North America
- Unit 10: Colonial America
- Unit 11: Ecology
Welcome, Tennessee reviewers!
Welcome to Amplify Core Knowledge Language Arts (CKLA), a comprehensive reading and language arts curriculum for Grades K–5 built on today’s rigorous standards. Amplify CKLA delivers superior results through a uniquely research-based approach, combining explicit foundational skills instruction with meaningful content knowledge in science, history, literature, and the arts.
By focusing deeply on building students’ knowledge base, Amplify CKLA levels the playing field for every child.
Amplify CKLA was developed by the Core Knowledge Foundation and Amplify.
Grades K–2 introduction
In grades K–2, Amplify CKLA is segmented into two distinct strands: Knowledge and Skills.
Skills Strand: Skills Strand lessons build a strong foundation for students through daily instruction in phonemic awareness, spelling patterns, decoding with engaging, decodable texts, writing mechanics, and writing structure and processes.
Knowledge Strand: It is vital to build students’ knowledge and vocabulary while they are still in the process of learning to read. In doing so, you better ensure their long-term success. CKLA’s Knowledge Strand is based on that very principle.
Grades K–2 student materials
Student Reader
Unlike other decodable texts, CKLA’s Readers feature engaging plots and characters, making the process of learning to read rewarding. Student Readers are provided for each unit in the program beginning in Kindergarten Unit 6.
Grades 3–5 introduction
In grades 3–5, the Skills and Knowledge strands are integrated. As part of the curriculum’s research-based design, students in grades 3–5 spend several weeks immersed in sequenced domains in science, history, and literature, deepening both critical literacy skills and background knowledge.
Grades 3–5 student materials
Student Reader
Rich in knowledge and diverse in content, Student Readers are the foundation of each unit as students dive into increasingly complex text and sharpen their analytical skills. From geology to the Middle Ages, students engage with a truly diverse range of topics.
Student Readers
- Unit 1: Classic Tales: The Wind in the Willows
- Unit 2: Animal Classification
- Unit 3: The Human Body
- Unit 4: The Ancient Roman Civilization
- Unit 5: Light and Sound
- Unit 6: The Viking Age
- Unit 7: Astronomy: Our Solar System and Beyond
- Unit 8: Native Americans: Regions and Cultures
- Unit 9: Early Explorations of North America
- Unit 10: Colonial America
- Unit 11: Ecology
Welcome, Tennessee educators!
On this site, you will find the following information to assist you as you review Amplify Core Knowledge Language Arts (CKLA): a program overview to get you started, the CKLA knowledge sequence, comprehensive program guides for a deeper dive into the research base and day-to-day instruction, and other useful information. You’ll also find a month’s worth of lessons for each grade level.
Amplify CKLA was developed by the Core Knowledge Foundation and Amplify.
Getting started
Welcome to Amplify CKLA, a comprehensive reading and language arts curriculum built on today’s rigorous standards. CKLA delivers superior results through a uniquely research-based approach, combining step-by-step foundational skills with meaningful content knowledge in science, history, literature, and the arts. By focusing deeply on building students’ knowledge base, CKLA levels the playing field for every child.
Read the program overview to learn more about CKLA’s unique approach.
Grades K–2
In grades K–2, Amplify CKLA is segmented into two distinct strands: Knowledge and Skills.
Skills Strand: Skills Strand lessons build a strong foundation for students through daily instruction in phonemic awareness, spelling patterns, decoding with engaging, decodable texts, writing mechanics, and writing structure and processes.
Knowledge Strand It is vital to build students’ knowledge and vocabulary while they are still in the process of learning to read. In doing so, you better ensure their long-term success. CKLA’s Knowledge Strand is based on that very principle.
Grades K–2 Resources
K–2 materials
Core components for grades K–2:
Teacher Guide
You’ll find step-by-step lessons that are comprehensive, engaging, and support every learner.
Activity Book
With an integrated approach to reading and writing, students practice new sound-spellings by reading them in diverse contexts and then writing in response to the text.
Reader
Unlike other decodable texts, CKLA’s Readers feature engaging plots and characters, making the process of learning to read rewarding.
Grades 3–5
In grades 3–5, the Skills and Knowledge strands are integrated. As part of the curriculum’s research-based design, students in grades 3–5 spend several weeks immersed in sequenced domains in science, history, and literature, deepening both critical literacy skills and background knowledge.
Grades 3–5 Resources
Grades 3–5 materials
Core components for grades 3–5:
Teacher Guide
Teacher Guides for each unit provide step-by-step guidance, clear lesson objectives, and formative assessment as well as differentiated supports to empower teachers with proven strategies and research-based tools.
Activity Book
Anchored by the unit’s text, Activity Books immerse students in content-rich learning for deeper comprehension. They provide daily opportunities for students to respond to text while applying knowledge and serve as formative assessments connected to each day’s objectives.
Reader
Rich in knowledge and diverse in content, Student Readers are the foundation of each unit as students dive into increasingly complex text and sharpen their analytical skills. From geology to the Middle Ages, students engage with a truly diverse range of topics.
Contact us
Chasity O’Quinn
Account Executive for East Tennessee
coquinn@amplify.com
(865) 599-5101
Ann Patterson
Account Executive for West Tennessee
apatterson@amplify.com
(704) 813-7757