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S1-05: How does coding fit in the science classroom? A conversation with Aryanna Trejo of Code.org

Podcast cover titled "Science Connections" featuring Aryanna Trejo, Season 1, Episode 5. It includes abstract illustrations of a globe and telescope, discussing coding in the science classroom.

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.

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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):

  1. 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.

Eric Cross (36:29):

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.

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What Aryanna Trejo says about science

“I would hear teachers saying things like, ‘Well I just can’t do coding, it’s just too hard for me.’ And I would ask them…Would you say that to your student about math or English? Be as kind to yourself as you would be to your student.”

– Aryanna Trejo

Professional Learning Specialist, Code.org

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.

Person with curly hair smiling, standing in front of a brick wall. Circular frame with decorative star in the corner.

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!

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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.
Digital Access

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 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. 

A three-column chart details: Drivers of Investigation, Standards for Mathematical Practice, and Content Connections, each with their respective codes and brief descriptions.

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.

A diagram showing three stages: Core instruction, Integrated personalized learning, and Embedded intervention, under Screening and progress monitoring with daily tiered support.

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.

Five steps for learning: 1. Activate prior knowledge, 2. Collaborate, 3. Refine ideas, 4. Guide to understanding, 5. Practice and extend for lasting 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. 

A chart displaying seven kindergarten math units with themes, number of instructional days, and assessment days, totaling 136 suggested instructional days.
Grade 1 instructional units overview showing 7 units on math topics, total suggested days is 153, with each unit listing instructional and assessment days.
Grade 2 math curriculum map showing 8 units with topics, number of instructional and assessment days, and total days; suggested instructional days: 156.
Seven instructional units are shown, each with a title, icon, number of instructional and assessment days, and total days; a note suggests 150 instructional days in total.
A Grade 4 math curriculum overview showing seven units with titles, number of instructional days, and assessment days; the suggested total instructional days is 152.
A curriculum map displays seven math units with icons, titles, instructional days, and assessment days, totaling 149 suggested instructional days.
A chart showing Grade 6 math units, each with instructional days, assessment days, and optional days. Total suggested instructional days is 142, plus 19 optional days.
Overview of Grade 7 math curriculum units, showing unit titles, number of instructional, assessment, and optional days for each, with a total of 125 instructional days plus 22 optional days.
Eight illustrated cards display Grade 8 math units, each with the unit title, topics covered, number of instructional and assessment days, and a total of 131 suggested instructional days.
Curriculum chart showing eight units split into two volumes, with topics, instructional days, assessment days, and optional days listed for each unit over an accelerated 6th-grade year.
A chart displays the breakdown of Accelerated 7 math units, indicating topics, number of instructional days, assessment days, and optional days for each of the nine units across two volumes.

Lesson Design and Structure

A four-part diagram shows: Warm-Up, Activities with a graph of student ideas to grade-level understanding, Synthesis with notes, and Practice and differentiation with students building a 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

A lesson plan timeline showing phases: Warm-Up (5–10 min, whole class), Lesson Activities (25–30 min), Synthesis (10 min), Centers (15 min), and Practice (time varies).

Grades 2–5

A horizontal flowchart shows a classroom lesson sequence: Warm-Up (5–10 min), Lesson Activities (35 min), Synthesis (10 min), and Practice (time varies); groupings vary.

Grades 6–8

A horizontal timeline shows four lesson segments: Warm-Up (5 min), Lesson Activities (30 min), Synthesis (10 min), and Practice (time varies).

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.

A table showing differentiation teacher moves with examples of representing groups in different ways, support prompts, and a stretch question about patterns with more teams.

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

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.
Digital Access

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.

A three-column chart details: Drivers of Investigation, Standards for Mathematical Practice, and Content Connections, each with their respective codes and brief descriptions.

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.

A diagram showing three stages: Core instruction, Integrated personalized learning, and Embedded intervention, under Screening and progress monitoring with daily tiered support.

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.

Five steps for learning: 1. Activate prior knowledge, 2. Collaborate, 3. Refine ideas, 4. Guide to understanding, 5. Practice and extend for lasting 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. 

A chart showing Algebra 1 units across two volumes, detailing instructional days, assessment days, and optional days for each unit, totaling 180 days plus 40 optional days.

Lesson Design and Structure

A four-part diagram shows: Warm-Up, Activities with a graph of student ideas to grade-level understanding, Synthesis with notes, and Practice and differentiation with students building a 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.

Flowchart showing classroom activity timing: Warm-Up (5 min), Lesson Activities (30 min), Synthesis and Show What You Know (10 min), Practice and Differentiation (time varies).

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.

A chart outlines three differentiation strategies—Support, Strengthen, and Stretch—with specific actions for each. A Math Language Development box is shown at the bottom.

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

LITERACY CHAMPIONS

The Science of Reading Star Awards

Making the shift to the Science of Reading is no small feat. Every day, educators like you are successfully improving student outcomes in schools and communities, and we’re eager to celebrate your accomplishments with the Science of Reading Star Awards.

We’re no longer accepting submissions for this year’s Star Awards cycle. See you next year!

A blue award plaque labeled "2026 Winner" is surrounded by colorful speech bubbles with a thumbs up and heart icon, decorative stars, and highlights achievements in the science of reading.

Get excited for the prizes!

Exceptional accomplishments deserve to be rewarded.

All award winners will receive:

  • Honorary Amplify Ambassadorship.
  • Amplification on our website and social media.
  • A Science of Reading starter library.
  • Enrollment in Science of Reading: The Learning Lab for each winner and a friend.
  • Tons of swag!

The grand prize winners in the District and School categories will receive access to an exclusive library of professional development resources. The grand prize winner in the Individual category will be given full conference registration and associated travel costs to The Annual Conference of The Reading League.

Recognizing leaders in education

Learning to read is nothing short of a transformation—and at the heart of this transformation are literacy educators harnessing the Science of Reading to ignite lifelong learning.

Science of Reading Star Award winners shine bright, going above and beyond to light the path for students nationwide. Be part of the celebration—help us recognize these heroes!

A woman with long dark hair, wearing a blazer and white top, smiles at the camera against a dark background, embodying confidence and expertise in the science of reading.
“Receiving this award is really an honor. It’s an amazing feeling to be recognized for work that I care so deeply about. At the same time I have to dedicate this award to the amazing educators that I work with, and the supportive administrators that we’ve had along the way.”

—Reena Mathew, Literacy Coach

Suffern Central School District, NY

An award category for everyone!

White icon of a school building with a clock on an orange, flag-shaped background, representing dedication to the science of reading.

District:
The District Captain

This award honors a district that exemplifies strong Science of Reading practices across the board.

A blue rectangular banner with a curled top-right corner displays a white book icon with horizontal lines, symbolizing the science of reading.

School:
The Literacy Legend

This award honors a school that has seen significant reading gains among their students school-wide when using the Science of Reading.

Yellow rectangular icon with a folded top-right corner and a white brain graphic in the center, representing the science of reading, set against a light gray background.

Individual:
The Background Knowledge Builder

This award is for showing the world that the Science of Reading empowers students with knowledge, context, and vocabulary from elementary through middle school.

A yellow, rectangular flag icon with a white graphic of a person wearing a helmet and holding a device, resembling an astronaut or robot—symbolizing exploration much like the science of reading uncovers new frontiers in literacy.

Individual:
The Changemaker

This award is for showcasing exemplary Science of Reading routines and practices, and serving as an inspiration to others on the journey.

An orange flag-shaped icon with a white pencil and ruler crossed in the center, symbolizing design or editing tools inspired by the science of reading.

Individual:
The Comprehension Champion

This award is for fostering deep understanding and critical thinking by expertly guiding students to make meaning from complex texts, ask thoughtful questions, and connect reading to their world and experiences.

A blue document icon with a white upward-trending line graph in the center, suggesting data analysis or statistics related to the science of reading.

Individual:
The Data Dynamo

This award is for expertly using data to drive instruction within an MTSS framework, identifying student needs with precision, and implementing targeted interventions that accelerate literacy growth for every learner.

Blue flag-shaped icon with two overlapping white speech bubbles in the center, representing communication or conversation, ideal for topics like the science of reading.

Individual:
The Language Luminary

This award is for outstanding success in developing the skills and strengths of emergent bilingual students and multilingual/English learners.

A yellow vertical banner with a white rocket icon in the center, a folded top-right corner, and subtle nods to the science of reading.

Individual:
The Science of Reading Rookie

This award is for a teacher in their first three years of teaching, already making strides with the Science of Reading.

An orange rectangular icon with a folded top-right corner, featuring a white fountain pen nib symbol in the center, representing tools used in the science of reading.

Individual:
The Writing Whiz

This award is for integrating writing instruction with the Science of Reading, cultivating articulate and confident writers through innovative and effective practices.

A person with wavy, shoulder-length blonde hair smiles at the camera outdoors, wearing a black top, black jacket, and a round pendant necklace. Greenery is blurred in the background, hinting at a relaxed moment away from studying the science of reading.
“I’ve been teaching for 17 years, so getting this award after starting to integrate the Science of Reading really validated what I was doing, solidified it in my classroom, and made me realize that I was doing the right thing after all.”

—Jennifer Dove, Grade 3 Teacher

Rockingham County, Virginia

Submit a nomination to the Science of Reading Star Awards!

Entry is quick and simple—just provide the required information and an overview of the nominee you think deserves recognition.

  • You may submit multiple entries, but please nominate for only one category at a time.
  • Your submission can include an overview of the educator, school, or district’s journey with the Science of Reading; how they overcame challenges; how they are empowering their students with the Science of Reading; how they implemented strong Science of Reading practices; and/or what results they are seeing.
  • The more specific you can be in your submission, the better! If data is a big part of your story, we’d love to hear about it.
  • As part of your entry, you agree to allow us to contact you about the details of your application.
  • A member of the team will be in contact by March 2026 if you are short-listed as a finalist.

Amplify Desmos Math California

Welcome, Math 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 Math 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.
Digital Access

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 for Math 1.

Evaluation Criteria Map

Linked here is the Evaluation Criteria Map for Math 1. Please note that you will need to be logged into the digital platform to access the links in the Evaluation Criteria Map.

Standards of Mathematical Practice

Linked here is the alignment of Amplify Desmos Math California to the Standards for Mathematical Practice at Math 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. 

A chart with three columns: Drivers of Investigation, Standards for Mathematical Practice, and Content Connections. Each column lists related activities and skills.

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.

A flowchart diagram showing "Screening and progress monitoring" linked to three phases: Core instruction, Integrated personalized learning, and Embedded Intervention, with daily support noted.

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.

Five steps for learning: 1. Activate prior knowledge, 2. Collaborate, 3. Refine ideas, 4. Guide to understanding, 5. Practice and extend for lasting 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. 

Mathematics I syllabus: Unit 1 to Unit 7 across two volumes, covering various math topics with instructional, assessment, and optional days detailed for each unit.

Lesson Design and Structure

Infographic showing a learning process: Warm-Up, Activities, Synthesis, and Reinforcement. Activities aim to increase student understanding over time.

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.

Flowchart showing classroom activity timing: Warm-Up (5 min), Lesson Activities (30 min), Synthesis and Show What You Know (10 min), Practice and Differentiation (time varies).

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.

A differentiation guide for Lesson 3 showing strategies for support, strengthen, and stretch, plus a section on math language development resources, all in a structured layout.

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, LAUSD educators!

Introducing Amplify Desmos Math California, a curiosity-driven TK–12 program that builds lifelong math proficiency. Each lesson poses problems that invite a variety of approaches before guiding students to synthesize their understanding of the learning goals. Students encounter math problems they’re eager to solve, while teachers spend more time where it’s most impactful—creating a collaborative classroom of learners.

Start by watching our welcome video to the right, then learn more about the program and begin your review below.

Curriculum overview

Watch the videos below for an overview of Amplify Desmos Math California:

Built for California

An educational worksheet on robots, featuring a graph with red, purple, and blue robot icons, and instructions for a warm-up activity.

The Amplify Desmos Math California program is designed around the vision articulated in the Mathematics Framework for California Public Schools: Kindergarten Through Grade Twelve 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.
  • 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 individualized support as they dive into the mathematics.

About the program

Taking the IM content further.

A laptop displays a math activity about platform heights and tube length, while a worksheet titled "Hamster Homes" is visible in the background.

Amplify Desmos Math California is a curiosity-driven program that builds lifelong math proficiency. Each lesson poses problems that invite a variety of approaches before guiding students to connect their understanding of the learning goals.

Students encounter math problems they’re eager to solve, while teachers spend more time where it’s most impactful: creating a collaborative classroom of learners.

We chose to base our program on the extensively field-tested IM K–12 MathTM authored by Illustrative Mathematics. IM K–12 Math is a problem-based curriculum. It asks students to grapple with well-designed and thoughtfully sequenced real-world mathematical problems to build their understanding of how to efficiently solve them.

Begin your review to see how we’ve taken the IM K–12 Math content further.

Begin your review

Using a Google Chrome or Safari web browser, click the orange button below or navigate to learning.amplify.com and select “Log in with Amplify.” Please note, these demo accounts expire on April 04, 2026.

K–8 English credentials

  • Username: t1.lausd_adm_k8@demo.tryamplify.net
  • Password: Amplify1-lausd_adm_k8

K–8 Spanish credentials

  • Username: t1.lausd_k8_spanish@demo.tryamplify.net
  • Password: Amplify1-lausd_k8_spanish

AGA credentials

  • Username: t1.lausd_aga@demo.tryamplify.net
  • Password: Amplify1-lausd_aga
Review now!

Welcome, LAUSD educators!

Introducing Amplify Desmos Math California, a curiosity-driven TK–12 program that builds lifelong math proficiency.

Our program fully aligns with LAUSD’s screen-time resolution. We are 100% print-based, with optional
technology resources available, in direct accordance with the school board’s newly approved guidelines.

Start by watching our welcome video to the right, then learn more about the program and begin your review below.

Curriculum overview

Watch the videos below for an overview of Amplify Desmos Math California:

Built for California

An educational worksheet on robots, featuring a graph with red, purple, and blue robot icons, and instructions for a warm-up activity.

The Amplify Desmos Math California program is designed around the vision articulated in the Mathematics Framework for California Public Schools: Kindergarten Through Grade Twelve 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.
  • 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 individualized support as they dive into the mathematics.

About the program

Taking the IM content further.

A laptop displays a math activity about platform heights and tube length, while a worksheet titled "Hamster Homes" is visible in the background.

Amplify Desmos Math California is a curiosity-driven program that builds lifelong math proficiency. Each lesson poses problems that invite a variety of approaches before guiding students to connect their understanding of the learning goals.

Students encounter math problems they’re eager to solve, while teachers spend more time where it’s most impactful: creating a collaborative classroom of learners.

We chose to base our program on the extensively field-tested IM K–12 MathTM authored by Illustrative Mathematics. IM K–12 Math is a problem-based curriculum. It asks students to grapple with well-designed and thoughtfully sequenced real-world mathematical problems to build their understanding of how to efficiently solve them.

Begin your review to see how we’ve taken the IM K–12 Math content further.

Begin your review

Using a Google Chrome or Safari web browser, click the orange button below or navigate to learning.amplify.com and select “Log in with Amplify.”

English credentials

Spanish credentials

Review now!

Welcome to Amplify Desmos Math California!

California educators, welcome to math that motivates. Introducing Amplify Desmos Math California, a curiosity-driven TK–12 program that builds lifelong math proficiency. Each lesson poses problems that invite a variety of approaches before guiding students to synthesize their understanding of the learning goals. Students encounter math problems they’re eager to solve, while teachers spend more time where it’s most impactful—creating a collaborative classroom of learners.

Explore the California Adoption Toolkit resources and discover more about the program in the sections below.

Built for California

The Amplify Desmos Math California program is designed around the vision articulated in the Mathematics Framework for California Public Schools: Kindergarten Through Grade Twelve 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.
  • 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 individualized support as they dive into the mathematics.

California Adoption Toolkit resources

Program Description

Linked here is the Program Description for Amplify Desmos Math California.

Our Major Conceptual Ideas Strategy

The renowned mathematician William Paul Thurston said that mathematics is about understanding. The essence of this perspective is woven into the California Mathematics Framework. The Framework is clear that mathematics calls for “original thought and connections of concepts” and that mathematics teaching should “position students as thinkers and members of the classroom community…to support students in seeing themselves as young mathematicians.”

When Amplify developed Amplify Desmos Math California, we built it with one clear priority: grounding it in student understanding. The Framework provided a basis in the Big Ideas, of course, but also in the Drivers of Investigation (DIs), Content Connections (CCs), and Standards for Mathematical Practice (SMPs). Using those components of the Framework, we organized student learning around how students would make sense of the mathematics.

In addition to lessons and learning experiences specifically designated as Explore lessons or Investigations, we utilized the structure of the DIs, CCs, and SMPs in each lesson. Not only is every lesson in our program tied to one or more of the Big Ideas and their connections with one another, every lesson is also framed around these additional components. Each Lesson Overview centers around these questions:

Why? Why are students learning this content?

How? How are students grappling with the mathematical concepts?

What? What contexts encourage students to apply their knowledge?

Each of these questions maps to one of the additional aspects of the Mathematical Framework. Addressing the “Why?” grounds the lesson in one or more of the Drivers of Investigation. Focusing on “How?” encourages students to develop the habits of mind described by the SMPs, becoming explorers in mathematics rather than passive recipients. And maintaining attention on “What?” centers students and teachers on the precise mathematical topics that they are exploring aligned to the four Content Connections.

The Big Ideas and the conceptual and pedagogical shifts in the California Mathematics Framework reflect a shared goal to center education on student understanding. The Amplify Desmos Math California team is eager to support educators and students in their transition to conceptual understanding through our High-Quality Instructional Materials, professional development opportunities, and continued support.

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.

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.

Drivers of Investigation and Content Connections

Amplify Desmos Math California incorporates the Drivers of Investigation and Content Connection 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.

A three-column chart details: Drivers of Investigation, Standards for Mathematical Practice, and Content Connections, each with their respective codes and brief descriptions.

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.

Contact us

For questions, samples, or more information, please contact your local Amplify Account Executive:

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
Account Executive
(818) 967-1674
broy@amplify.com		 San Diego County
Kirk Van Wagoner
Senior Account Executive
(760) 696-0709
kvanwagoner@amplify.com
Under 2300 students in Bay Area, Sacramento Valley, and Northern Counties
Kevin Mauser
Lead Account Executive
(815) 534-0148
kmauser@amplify.com		 Under 2300 students in Southern CA, Central Coast, and Southern Central Valley Counties
Charissa Snyder
Account Executive
(720) 936-6802
chsnyder@amplify.com		  

The English language arts program designed to prepare Arkansas middle schoolers for high school and beyond.

Amplify ELA is a blended English language arts curriculum designed specifically to support students in grades 6–8 and prepare them for high school and beyond. With Amplify ELA, students learn to tackle any complex text and make observations, grapple with interesting ideas, and find relevance for themselves.

  • An illustration from Amplify ELA
  • A student reading "Summer of the Mariposas"
  • students collaborating and using laptops
  • An illustration of the Space Race from Amplify ELA

Built for middle school teachers and students

Built specifically for middle school, Amplify ELA is an interactive core curriculum that brings complex texts to life. Amplify ELA’s 100-Day Pathway is a built-in guide to covering required content for each grade level while allowing teachers time to add supplemental lessons and activities.

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All-green rating on EdReports

The results are in! Amplify ELA received a near-perfect score by the independent review group.

Our approach

Amplify ELA is the ELA program designed for middle school. It offers rich texts that are a delight to teach, better connections with your students through powerful differentiation and assessment tools, and step-by-step instructional guides that save you time and simplify your day.

Explore more research behind the program

We empower students to become critical thinkers.

With text always at the center, students are encouraged to make meaning for themselves. Rather than focusing on right or wrong answers, they develop ideas and opinions on relevant, real-world, texts.

Una mujer joven que usa atentamente una tableta para acceder al programa Amplify ELA en una habitación iluminada por el sol, con el cabello castaño recogido.
A student using a laptop

We provide six levels of differentiation.

Multiple entry points and differentiated supports allow every student, regardless of fluency or ability level, to engage deeply with the same complex texts and rigorous curriculum.

We assess while you instruct.

Formative assessment reports provide a continually updated picture of how each student is progressing with key skills and standards. Each learning moment provides a small piece of data, allowing you to keep teaching while building a clear understanding of student performance.

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Download a free white paper

Beyond “make it fun”: Four principles of true engagement in middle school ELA

Download the white paper

What’s included

Amplify ELA is a rigorous core curriculum that empowers teachers and engages middle school students.

Student edition

Available digitally and in print, the student materials guide middle schoolers through complex texts and writing by:

  • engaging students with high-quality narrative and informational texts
  • providing videos, audio supports, and digital experiences that capture their attention
  • keeping all of their writing in one place with a personal writing journal

Teacher Edition

Available digitally and in print, the Teacher Edition contains all the information teachers need to facilitate classroom instruction, including:

  • detailed lesson plans
  • video teacher tips embedded in the lesson
  • standards alignment and exit tickets
  • real-time differentiation strategies
  • robust reporting

Interactive Quests

Quests are fun, week-long immersions into a specific, multilayered topic. They enable students to practice analytical reading, writing, speaking, and listening skills—all while building a strong classroom community.

Digital library for independent reading

The expansive Amplify Library includes more than 650 digital fiction, nonfiction, classic, and contemporary titles.

ELA_teacher_resources_1

Amplify ELA makes teachers’ lives easier

We help teachers make sure the standards are covered, the skills are taught, your students are scaffolded and encouraged, and the test is prepped.

  • Embedded differentiation to support all readers.
  • Informative and streamlined assessment system.
  • Robust reporting that tracks progress.
  • Powerful feedback tools.
All materials

Amplify ELA California

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Core curriculum programs

We strive to create low floors and high ceilings for students in our core curriculum programs, to borrow a phrase from learning theorist and Massachusetts Institute of Technology professor Seymour Papert. In other words, we engage all students with challenging content by creating multiple entry points and different modalities to access the content. We also empower teachers with tools to provide robust scaffolding and differentiated instruction (the stairs to climb up to the high ceiling), to ensure that all of their students can fully engage with rigorous subject matter.

See what the evaluators at EdReports have to say about Amplify’s high-quality core curriculum.

Two students in school uniforms focused on writing in their notebooks at a classroom desk during a science lesson.
Illustration of a bear on a rock overlooking a mountain landscape with a badge overlay reading "read the report EdReports review year 2011.

Amplify CKLA

Using a fundamentally different approach to language arts, Amplify Core Knowledge Language Arts (CKLA) is a PreK–5 program that sequences deep content knowledge with research-based foundational skills. CKLA met expectations and received green ratings from EdReports. Learn more about the program.

Read the review on EdReports

Amplify ELA

Built specifically for middle school, Amplify ELA is an interactive core curriculum that engages students by bringing complex texts to life. ELA received near-perfect scores from EdReports. Learn more about the program.

Read the review on EdReports
Collage image featuring a girl with a crown looking at a sunset, a boy reading about the Amplify ELA program, and the "read the report review year 2020 edreports" logo
Two teenagers wearing safety goggles conduct a science experiment with beakers and liquids on a table, under an "EdReports 2020 Review" text banner.

Amplify Science

Amplify Science empowers students to think, read, and write like real scientists and engineers. Amplify Science K–8 received all-green ratings in EdReports’ review of national science curricula. Learn more about the program.

Read the review on EdReports

Amplify Desmos Math

Coming soon: Amplify Desmos Math is designed around the idea that a core math curriculum needs to serve 100 percent of students in accessing grade-level math every day. The program delivers engaging math lessons that are easier to teach, collaborative problem-solving experiences both online and off, and data that drives performance. (Amplify Desmos Math grades K–Algebra 1 are available to pilot starting back-to-school 2024.)

Learn more
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Ready to learn more?

Fill out this form, and we’ll be in touch with you shortly.

The power of productive struggle in K–5 math

A cartoon pizza cut into slices with a serving spatula in the center, flanked by colorful shapes and a cartoon animal on the right—an engaging way to spark curiosity about procedural fluency and fluency in math.

Struggling is not necessarily fun. It can be uncomfortable and frustrating. It can even feel like a great reason to give up.

But struggling and learning often go hand in hand. The key is for that struggle to be productive—for it to feel like something you worked through until you were successful, providing the confidence you need to tackle the next hard task.

That’s especially true—and essential—in math learning.

The key is productive struggle: the kind of effort that stretches students’ thinking without shutting them down. When designed intentionally, math activities for elementary students can challenge learners while still supporting confidence, curiosity, and persistence.

Here’s more about how productive struggle helps math students succeed.

What is productive struggle?

Productive struggle refers to students grappling with challenging problems that are not immediately solvable, but still within reach. It’s the space where students test ideas, make mistakes, revise strategies, and slowly build understanding.

Research shows that productive struggle helps learners move beyond surface-level memorization and toward deeper, more durable learning.

Rather than being told exactly what to do, students are encouraged to reason, explain, and persevere.

This doesn’t mean leaving students to flounder. Productive struggle requires clear goals, thoughtful scaffolds, and meaningful tasks so students know what they’re working toward and believe they can get there.

The role of growth mindset in math learning

Productive struggle is closely tied to another key idea: growth mindset.

A growth mindset is the belief that ability comes not from innate, baked-in talent, but through effort, strategies, and learning from mistakes. In the math classroom, this mindset helps students see challenges not as threats, but as opportunities.

When teachers communicate high expectations and normalize mistakes as part of learning, students are more willing to take risks. They begin to stop saying, “I can’t do this math problem,” and start saying, “I’m not there yet.”

This shift matters, especially in elementary grades. Students who develop a growth mindset early may be better equipped to avoid math anxiety and to handle increasingly complex math concepts, because they’ve learned that struggle is not a sign of failure, but part of the process.

Why struggle feels risky—and why it’s worth it

Supporting productive struggle can feel risky for teachers. Classrooms are busy. Time is limited. And no one wants students to feel frustrated or discouraged.

But avoiding struggle altogether creates its own problems. When math activities are too procedural or overly scaffolded, students may complete tasks without truly understanding them. Over time, students may come to believe that math is about following steps rather than making sense of ideas.

By contrast, well-designed struggle builds investment. Students engage more deeply when they’re asked to think, explain, and choose strategies. They develop problem-solving skills, perseverance, confidence, and a stronger sense of ownership over their learning.

What productive struggle looks like in practice

In classrooms that support productive struggle, students are actively involved, even when tasks are challenging. You might hear students explaining their reasoning, comparing strategies, or revising their thinking after a mistake.

Effective math activities for elementary students include:

  • Multiple entry points so all learners can begin.
  • Opportunities for students to explain why their strategy works.
  • Support for more than one correct approach.
  • Clear expectations paired with flexible pathways.

Even in kindergarten math activities, productive struggle for the youngest learners might look like counting, sorting, or representing numbers in different ways, paired with questions that prompt reasoning rather than quick answers.

Students need tasks that are mathematically meaningful, paired with structures that help them persist: opportunities to talk, visual representations, strategic questioning, and time to reflect.

In this way, struggle builds math muscle. Productive struggle helps students feel on top of their math game—and ready to learn more.

Math that motivates your K–5 students

As a K–5 teacher, your day is a constant balance of subjects, personalities, and priorities. With so many different dynamics and responsibilities, math class shouldn’t be another struggle to muscle through!

That’s why we’ve compiled a wealth of resources and activities to help you engage students; meet instructional goals; and encourage fluency, number sense, and discussion in your classroom. 

Three children paint the walls of a room; one holds a paper with the fraction 2/3, while math symbols and a tree appear in the background.
A booklet titled "The Power of Fluency: Cultivating Flexible, Confident Problem-Solvers" with an illustrated cover and an open page showing text and graphics about classroom fluency.

The power of fluency

Teachers work to achieve so many outcomes during their math block. While balancing multiple priorities, it’s important to remember that procedural fluency remains integral to student learning. Access this guide to unpack the power of fluency and find free math fluency practice to use in your next lesson.

Download now

10 low-prep, high-impact math activities that get to some serious math

Envision your classroom engaged in a difficult math task—all students are participating, leveraging different scaffolds that you intentionally prepared ahead of time. Engagement is high, and students are both challenged and motivated. Make this a reality in your school with our free activities designed to encourage productive struggle while reaching all learners.

Access now
A teacher holds a clipboard while a student points at a chalkboard labeled "Guinea Pig," "Millipede," and "Goldfish" in a classroom setting.
A presentation slide titled "Three Practices to Support Problem-Based Learning" features students and teachers engaged in classroom activities and math instruction.

Three practices to support problem-based learning

As educators, we want all students to develop a rich and deep understanding of the math they experience in our classrooms. A problem-based learning approach supports this by centering problem-solving in ways that build lifelong mathematical proficiency. Read this guide for practical tips on introducing problem-based learning and deeper conceptual understanding into your math classroom.

Download now

Best practices from real educators like you

Learn tried and true strategies for leveling up math instruction from Beyond My Years podcast guests like Amplify’s own Dan Meyer, teacher and My Kindergarten Math Workbook author Keri Brown, educator and speaker Mike Flynn, teacher and I Hate Math author Ian Brown, and more!

More free resources for K–5 educators

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K–5 Insider

Sign up for our monthly email to get new K–5 content and activities directly in your inbox.

sign up 

A printed guide titled "What are math routines, and how can you use them?" for grades K–5, with instructions and example math routine cards displayed.

K–5 instructional routine cards

Find easy-to-implement routines to keep students interacting and engaged with a lesson.

Download

A student and a teacher look at a laptop screen and smile in a classroom with colorful posters on the wall.

Math that motivates: Success stories

See how real teachers and students are unlocking new levels of engagement and comprehension, proving that everyone can be a math person.

LEARN MORE 

Ready to make every student a math person?

Connect with a product expert today.

FAQ for K–5 educators

Procedural fluency is the ability to use procedures flexibly, accurately, and efficiently to solve problems. Procedural fluency goes beyond memorization—students develop fluency when they understand number relationships and can choose from multiple strategies based on the numbers involved.

Students who understand why procedures work feel confident tackling challenging problems. When students can choose strategies that make sense to them, rather than relying on rote memorization, they develop agency and see themselves as capable mathematical thinkers.

Understanding how numbers connect helps students develop flexible thinking and multiple solution strategies. Timed tests often prioritize speed over understanding, which can create math anxiety and discourage the productive struggle that deepens learning.

Teachers can achieve this balance by using a predictable routine: warm-ups for fluency practice, a core problem-solving activity during which students explore multiple strategies, and structured discussion to connect different approaches. This structure ensures both skill-building and mathematical discourse happen daily.

Synthesizing learning means bringing the lesson together by highlighting the key mathematical idea that students have just explored. After students share strategies, the teacher helps them make connections between different approaches and names the big takeaway, often through a brief summary or exit ticket.

The Five Practices for Orchestrating Productive Mathematical Discussions are: 1) Anticipating student strategies before the lesson, 2) monitoring student work during the activity, 3) selecting specific students to share, 4) sequencing presentations in a purposeful order, and 5) connecting different strategies to the mathematical goal.

Productive struggle is when students grapple with challenging problems that require genuine thinking, but that remain accessible with appropriate support. It’s essential for deeper understanding, because it compels students to think critically, test strategies, and build perseverance, moving beyond surface-level memorization.

They can celebrate mistakes as learning opportunities and emphasize that understanding develops through effort and persistence. They can also create a safe classroom environment in which all students feel comfortable sharing their developing ideas and foster structured discussions during which multiple strategies are valued, helping students see that there’s more than one right way to think mathematically.

These are problems accessible to all students (that’s the low floor) but open enough to challenge advanced thinkers (that’s the high ceiling). Tasks like these allow multiple entry points and solution strategies, making them ideal for generating rich classroom discussion in which every student can participate meaningfully.

Such routines build number sense and fluency while making discussions predictable and low stakes. These brief, structured activities (5–10 minutes) activate prior knowledge, help students see number relationships, and give everyone practice explaining their thinking—all without requiring extensive preparation or materials.

They can do so by maintaining meaningful objectives while providing varied supports—ensuring that students understand what’s being asked, offering manipulatives and visual tools, allowing partner discussion before whole-class sharing, asking guiding questions without giving away the answer, and strategically grouping students. The goal is supporting access to challenging work, not making it easier.

S4 – 02. Bethany and Dan share their math biographies

Promotional graphic for "math teacher lounge," season 4 episode 2, featuring photos and names of math teaching guests Bethany Lockhart and Dan Meyer.

In this episode, co-hosts Bethany Lockhart Johnson and Dan Meyer get personal and share their “math bios”—their early experiences with math and how those experiences turned them into the educators they are today.

Explore more from Math Teacher Lounge by visiting our main page

Download Transcript

Dan Meyer (00:00):

We’re recording. What’s up, everybody. This is Dan Meyer with Math Teacher Lounge.

Bethany Lockhart Johnson (00:08):

And I’m Bethany Lockhart Johnson. We are so excited to be back. Season Four, Episode Two. Hi, Dan.

Dan Meyer (00:16):

Hey, Bethany, how are you doing today?

Bethany Lockhart Johnson (00:18):

I’m so excited to be talking with you! You know, as we record this, our reunion at NCTM is getting closer and closer.

Dan Meyer (00:28):

The NCTM live show is gonna be bonkers. I don’t think people are ready for it. You think you know what we’re about on MTL from listening to us, but the live show is gonna be outta control. You cannot imagine how many clowns and elephants Bethany wants to have at the live show. We’re still—we’re trying to talk her down from like three to one, but we’ll see.

Bethany Lockhart Johnson (00:44):

All I want is the t-shirt cannon. Because I used to go to these baseball games and they would have a t-shirt cannon. And I thought, I wanna operate a t-shirt cannon! So like, if I could be standing on stage aiming t-shirts at people who are jumping up and down requesting a t-shirt? I don’t know. Doesn’t that sound fun?

Dan Meyer (01:01):

Sounds awesome. High point of my college education was catching a t-shirt. No, it was—it was a burrito. It was a burrito cannon. But I think it was just a t-shirt cannon, but it was a burrito cannon. And I caught a burrito at a game and it was probably the most memorable moment of all of college education for me.

Bethany Lockhart Johnson (01:16):

Was the burrito still warm?

Dan Meyer (01:18):

Oh yeah. I think it got—like, I think it might’ve been warm at one point and then it got warmed back up through the muzzle velocity of the cannon. So it was a pretty great system they had going on there. <Laugh> Yeah. <Laugh> Anyway, I’m off topic, but, we’re thrilled to—I’m thrilled to chat with you and we’re thrilled to be listened to by you folks out there in MTL land. In the lounge itself. We got a fun show today.

Bethany Lockhart Johnson (01:40):

So if you listen to Episode One—which if you haven’t, hope you go back and listen to it—if you listen to Season Four, Episode One, you’re gonna hear—we asked Huon, KT, who is this delight of a joyful teacher. We asked her to talk to us about what’s her math bio. And we want to ask all of our guests—like, I wanna go back and ask every single guest we’ve ever had to tell us their math bio.

Dan Meyer (02:06):

Yep.

Bethany Lockhart Johnson (02:06):

Because, while seemingly simple in nature, our students enter our math classroom already having had this relationship with math and these notions about their role in math or what they think about math. And it impacts our school year with them if we’re a teacher. And it impacts our relationship with math as we move through our education and beyond. Right? And I I’m so excited about this question, ’cause I think it also ties into this theme for Season Four, which is joyful math, and diving into “When has math felt joyful? When has it not? Does it feel like—how do we think about how our math bio, our relationship with math, has evolved into a joyful or less joyful place?”

Dan Meyer (02:54):

I get it. And what’s really key here, I think, is that teaching more than other professions is a generational profession. You know what I’m saying? Like, no one is like, “Well, you know, I sold insurance to you and now you’re selling insurance to, you know, my grandkids; that’s amazing!” But people are always posting photos when, like, you teach someone who then becomes a teacher later. Teaching is a generational sort of thing. So the kinds of joyful experiences that we offer or don’t offer students now affect the experiences that students who haven’t even been born yet will have, you know, some 20, 30 years later. That, to me, is a trip. And well-worth exploring, you know, how we got here, mathematically speaking.

Bethany Lockhart Johnson (03:39):

I remember a friend had sent me this image of an assignment that her son got that was asking for their Mathography. They wanted to know about their history of mathematics. And this was their first assignment. And this teacher, I would like to imagine, read them all and used it to inform conversations about students’ relationship with math. And, you know, some of the questions they asked were thinking about whether you consider yourself, quote, unquote, “good at math.” Like “what kind of experiences have you had? What do you like or dislike about math? What is, you know—what do you expect to learn in math this year?” Just asking students to actually pause and examine and reflect on their relationship and then also looking forward to, like, what kind of a classroom community do we wanna create? And I loved that assignment. And yeah, so today’s episode Dan, guess what?

Dan Meyer (04:32):

What’s going on? What’s happening?

Bethany Lockhart Johnson (04:33):

I figured we should ask each other about our math bio.

Dan Meyer (04:39):

I think the people out there would love to know this about us. ‘Cause you know, we’re both awesome. But also what’s really cool here is that like, I don’t know this about you. Like not, not a lot. You know, the folks at Amplify, they kind of assembled me and Bethany together in the same way that record labels assembled pop boy bands, girl bands, that kind of thing, back in the day. You know, grabbing some stars from screen or film and just like throwing ’em together and saying, “All right, now you’re here to perform together.” And so it’s just a really good moment for us to, like, settle back and just know who we’ve been working with for the last three seasons and change here. I love it.

Bethany Lockhart Johnson (05:15):

Well, I don’t know. I don’t actually agree with that, Dan. Because don’t you remember? We knew each other beforehand. And while I would like to think of us as…oh, I’ll say One Direction—well, no, One Direction is now defunct. Who’s another band that got formed by one of those shows and is still together and still—

Dan Meyer (05:33):

BTS! K-Pop, you know! Let’s go!

Bethany Lockhart Johnson (05:35):

K-pop. BTS.

Dan Meyer (05:38):

Let’s go, Bethany <laugh>.

Bethany Lockhart Johnson (05:39):

So can we incorporate some K-pop into the NCTM Math Teacher Lounge live episode? Don’t answer now. Don’t answer now. OK. So not only are we gonna share our math bios, but we want to encourage you listeners to share your math bio with somebody in your life. It could be a child in your life, maybe talking to your kiddo about what was it like. What was math like for you? It could be a student that you have. It could be a partner, a friend, a parent. I mean, the sky’s the limit. Share your math bio. And most of all, share with us. We wanna hear about your math bio and you can share it with us at Twitter, at MTLShow, or in our Facebook group, Math Teacher Lounge.

Dan Meyer (06:26):

Stop on by, please. All right. I’m gonna just share like, just a couple of quick, signposts. Not the full bio. Gotta leave them wondering about something here. But here’s a few quick highlights and lowlights of my math bio and how, maybe, it made me the teacher that I was and the educator I am. Is that cool?

Bethany Lockhart Johnson (06:44):

Wait, I didn’t even, I didn’t ask you yet.

Dan Meyer (06:46):

Ask me what?

Bethany Lockhart Johnson (06:47):

Hey, Dan!

Dan Meyer (06:49):

Is there like a magical word? Like, what’s your math bio? <Laugh> Oh, go for it. No, no, that’s right. They won’t know what I’m talking about. Why is he talking about his math bio? Bethany—

Bethany Lockhart Johnson (06:57):

That whole lead-in that we just gave? They might not know.

Dan Meyer (07:00):

Yeah. We just talked about math bios for the last 20 minutes. But yeah, they might not know what we’re—

Bethany Lockhart Johnson (07:04):

<laugh> So Dan, why don’t you go first? ‘Cause I know you were gonna ask me to go first, but why don’t you go first? Dan? What’s your math bio?

Dan Meyer (07:12):

Oh, wow. Well, thank you for the formal invitation to share my math bio, Bethany Lockhart Johnson. So, I’ll just share—I just wanna share a couple items here, not the full history. Gotta leave ’em—leave a little mystery in there, you know what I’m saying? But here’s a few highlights and lowlights, and I think what it means for me as an educator. So, I was homeschooled for eight years. That was big—did a lot of math learning on my own. Couple of lowlights from that, a lot of highlights, in terms of just like being able to, like, learn at my own rate and just jump on ahead and pursue different wacky things. But I tried to switch into public school in fourth grade and I lasted, um, four hours. I didn’t even go to class. I enrolled and then it was like, boom, I was out of there. Because we went to the school; we met the teacher, saw the room, very nice person and place. But I got the homework assignment and the homework assignment was gibberish. I had no idea what to do and such was this feeling of just, like, despair and hopelessness, I was like, I cannot be a part of this. I remember the assignment. It was about identifying scalene, isosceles, and equilateral triangles. I’ll tell you this: I am quite good at that now. But at the time, like, I didn’t know what those words meant. And you know, at that moment we had Encyclopedia Britannica, could not Google this or even Ask Jeeves or AltaVista this so well back then. It just—it was an entry moment of failure and realizing that so much of math is like a, kind of a social kind of construct. And if you’re not part of that social circle, what can you do? So that was a bummer. Another bummer was eighth-grade math, learned it all by way of videotape. You know, put in the tape and watch—not gonna say the person’s name and not this person’s fault—but it was just like watching someone work on a whiteboard. Kind of a precursor to Khan Academy, kind of a drag. Went to high school—

Bethany Lockhart Johnson (09:02):

Wait, wait, wait, wait. We were—I’m not ready to jump to high school. Wait. Can you pause for just a second?

Dan Meyer (09:06):

Yeah. Rock on.

Bethany Lockhart Johnson (09:07):

I just need you to go back to the triangle thing. So in that moment, what did that mean for you that you had had all these experiences with math and then you encounter math in a completely different sphere, a public school, and it did not have a connection or meaning to you because prior to that, it sounds like it was pretty positive. Right? Explore these things you’re curious about; there’s not, like, a level you need to stick with…

Dan Meyer (09:33):

Yep, yep. Yeah. I think that’s right. Maybe it was a little bit of a classic, like, “Oh, I didn’t have a growth mindset; my mindset was like, ‘Oh, I’m good at math because I am, you know, born that way,’” and all of a sudden, that identity was, you know, thrown into question. And, you know, my foundation was all of a sudden quite shaky. And yeah, that’s—you know, I think I taught a lesson recently where I was like, “Hey, this whole thing with a less-than or equal-to sign and a greater-than or equal-to sign, like what those signs are: it’s just, it’s language. And if it’s confusing to you, it’s not because you’re bad at math; it’s ’cause language is oftentimes confusing ’cause people have to agree on it.” So I dunno, that sort of thing is kind of filtered in, filtered back in periodically, some sympathy for like how a lot of math is like just socially agreed upon ways of working with, you know, numbers, shapes, patterns, that kind of thing.

Bethany Lockhart Johnson (10:20):

OK.

Dan Meyer (10:21):

Anyway.

Bethany Lockhart Johnson (10:21):

  1. And in this home school—I have a lot of questions about that, but I’ll stick to one—were you in a community of people that you talked about these math ideas with? Were you homeschooled solo? You have a sibling, so I think you were together, right?

Dan Meyer (10:39):

Yeah. Yeah. I’ve got a twin sister. So we were, you know, like, right on with each other the whole way through there. And yeah, so we had—but it wasn’t, it wasn’t like a—it was a lot of individual work, with my flavor of homeschooling.

Bethany Lockhart Johnson (10:54):

  1. Got it. And the tapes—wait, before you go to high school, the tapes, the VHS tapes, which I’m just loving this image—

Dan Meyer (11:02):

Yeah.

Bethany Lockhart Johnson (11:02):

Was that a positive experience? Was that because that was an area of math that whoever was homeschooling you wasn’t that comfortable with? Why was it that route for the tapes, and what was that? Was that joyful for you?

Dan Meyer (11:15):

Yeah, definitely not joyful. Yeah, it was like, if you had questions, you couldn’t really ask them of the VHS tape. It didn’t work out so well in that way. And it was a lot of operational-type math. It was, you know—there was no give and take; it was all kind of take. From the video teacher. And yeah, I was doing that because my homeschool teacher, my mom, who is very smart in lots of areas, did not have the math knowledge or confidence, especially to help with math at eighth grade. And that was a big reason why, flash-forward to the next year, went to high school.

Bethany Lockhart Johnson (11:48):

Nice segue. OK.

Dan Meyer (11:50):

<laugh> You caught up to high school…I encountered just like four years of just crazy-good, just bonkers-good math teachers who just really changed a lot for me. Especially, Mr. Bishop and Mr. Cavender, very cool folks who did a lot. And especially, I think Mr. Bishop and Cavender both modeled for me what curiosity from a knowledgeable adult looks like. Like someone who, you know, now I can say to myself, “Oh, they were kind of like putting on an act of being very curious about answers they were hearing for the 2000th time from a student,” let’s say, but what a powerful experience that was for me to feel like, “Oh, wow, my thoughts are interesting to someone besides myself.” I got like, maybe it’s two real highlights that I’ll just point to, from my math bio that made me the math teacher and person that I am. Let’s see here. Maybe three, if you you’ll indulge me. One is just like the idea that you could do math wherever you have your brain, a pencil and a paper. And so I remember like in high school, I was in church with my family and kind of a little bit bored of whatever’s going on. And I just had the Bolton and I like drew a pentagon, a regular one, then a hexagon, a regular one, and kept on drawing, like adding sides to the shape. And it was like, it was becoming a circle. And, you know, I was able to take the area of each of those shapes and say, you know, “What happens as you send the number of sides to infinity?” And watch as the formula for area of a circle, Pi R squared, popped out. And it was kind of a literal religious experience, in that moment, just like, “Wow, like my brain’s so cool and math is so cool and paper and pencil’s so cool.” And so there’s that. Just that kind of experience was pretty awesome. And then I would just say like, I’ve had some really fantastic experiences with math in the world itself. Stuff like—let’s see, this is gonna invite more questions from Bethany, probably, maybe I should avoid—I got, I have a Guinness—I have a Guinness world record that’s almost 20 years old. This Guinness world record is—it’s old enough to drive basically at this point. And almost old enough to drink. But like it was—it was a record for chaining the longest paper clip chain together in 24 hours. And the only way I was able to break that record was through mathematics. Where, like, I would be finishing a box of clips. And I would say to my buddy who was there, “I just finished a box of clips.” And that person would type in the number of clips that I had just done. And then a mathematical formula that I had created would tell me how many—how long the chain was at that point. It was being rolled around a spool. And like, it’s just like, wow. So math just made this possible. You know, math revealed that the record I was trying to beat was beatable, because I did the math on it. It was, like, thousands of feet long in 24 hours. And other folks might be like, “Oh, like, that’s that’s huge!” But me, I was like, “All right, let’s divide this out. You know, divide by 24 hours in a day, divide by 60 minutes an hour, 60 seconds in a minute. Oh, that’s like one clip every four seconds. That’s really slow.” You know, think about that <counts aloud>, “Clip, two, three, four. Clip two, three…” It was just slow. So math helped me, you know, wreck that record. Which to my knowledge still still stands. Don’t get any ideas, Math Teacher Lounge Folks! Is this news to you, Bethany? You haven’t blinked in the last, like, five minutes. I’m curious if this is new.

Bethany Lockhart Johnson (15:20):

It is news to me. And I have so many questions. Because OK, if four seconds was slow, so then what was your like—so then I’m assuming a hundred clips per box? Like, what was the rate, you know, per box? How long did it take you to complete a box? What did this friend like? Did this friend stick with you for the whole 24 hours? Did you really do it for 24 hours? Or once you beat the record, did you rest? How did you account for biological function? Like, needs? Like a restroom?

Dan Meyer (15:51):

<Interrupting> Like what?

Bethany Lockhart Johnson (15:51):

Eating.

Dan Meyer (15:51):

Like what, Bethany? OK.

Bethany Lockhart Johnson (15:52):

Um, Sleep.

Dan Meyer (15:55):

So yeah, maybe we dive into some of the specifics in a different time.

Bethany Lockhart Johnson (15:59):

Just tell me one of ’em. Tell me one.

Dan Meyer (15:59):

I’ll just say. So as to discourage other Math Teacher Lounge listeners from taking this on—back off of the record, folks!—this was back in college, so I was a little more limber back then. But I did one—I think it was 1.8 seconds per clip. For an entire 24 hours. Just like, so just like think about it, would you? If you’re gonna step to me on this one, just think about that, OK? And then, and then, you know, make an informed decision.

Bethany Lockhart Johnson (16:28):

Wait. Wait, wait, I just wanna tell you one thing. I’m picturing somebody with a straw, and like, giving you water as you keep clipping. I’m picturing, like, music, I…

Dan Meyer (16:37):

That’s not far. That’s not far. That’s not far from—yeah.

Bethany Lockhart Johnson (16:40):

So many questions! OK. Go on. Sorry, sorry, sorry. Go on. This is your bio.

Dan Meyer (16:44):

We gotta, I gotta wrap this up. I wanna hear your bio. But, like, I would just say like this move to this sense that math is actually a thing that’s useful for more than just a grade; it’s useful for more than just, you know, the societal, you know, adulation that comes from being a math nerd. That kind of thing. And so that, I think that affected a lot of math teaching for me. And, if I gotta, like, summarize math teaching itself in a journey, it went from like, “Hey kids, aren’t I awesome?” to, “Hey kids, isn’t math awesome?” to “Hey kids, aren’t you awesome?” And like that journey was facilitated by lots and lots of people, you know, a lot of personal growth, but at this point, at one point I was like, “Hey, math can help you get records and whatnot. It’s really useful.” And now I’m like, “Wow, your brain’s just doing just really interesting things. I can help you understand how interesting those things are, and maybe make them more interesting, or interesting in a different way, with some help here.” Let’s put a pin in that. That’s the math bio.

Bethany Lockhart Johnson (17:50):

  1. So I have no doubt that if you ask someone in your life, listeners, for their math bio, that you will discover things about them that you never knew. Literally the questions that I have…I have so many question. And Dan is very good at, you know, bringing me back. Bring me back, like, come on, come on. But I just wanna say, overall, your journey seems pretty joyful. It seems pretty joyful. It seems pretty full of confidence. I don’t wanna say “ego” in a negative way, but I wanna say you were buoyed by these experiences that allowed you to feel like math was a place for you to thrive.

Dan Meyer (18:36):

Right.

Bethany Lockhart Johnson (18:36):

Where you could try out things. You could try it out and just, “I could do that!” Right? Like…your relationship just felt very, like…you felt like you had autonomy, agency, perhaps much like you, you operate in this world. Dan, is that, is that right <laugh>?

Dan Meyer (18:54):

Yeah, I think it’s fair to say. And without telling too much of her story, my twin sister with whom I share most things, including genetics, you know—she had a very different experience in math early on. She’s brilliant. She’s a doctor. And not, you know, the book kind of doctor that I am, but like a real, you know, medical doctor. She’s brilliant. But we were—we encountered different messages about who math was made for, early on in, you know, in our entire math learning. And she—we both digested the messages that we were sent, and took, you know, different, different paths because of them, for sure.

Bethany Lockhart Johnson (19:31):

Funny how that works. I thank you, Dan. I do. For in all sincerity, I appreciate you sharing that. And I think that it’s exciting to hear how it influenced your teaching. It feels like you want to cultivate those experiences for your students. And I’ve been in the room when you’ve presented; I was in a room where you taught a class live. It felt like you were making space for the students to have these aha moments. And it feels like in your work at Desmos, and now Amplify, you’re trying to create these products that allow folks to recreate these amazing math moments. Right? And that it’s for everyone and that it’s accessible and it can be very positive. I feel like I have this new perspective on kind of the energy you bring to your teaching. So thank you for sharing that.

Dan Meyer (20:24):

Yeah. Been a pleasure. Thanks for your questions here, Bethany. And it’s been—it’s been fun to reflect on it. And I do—I do feel very lucky in lots of ways. Privileged. Lucky. I know, like—I think the world has been set up for my success in lots of ways, as who I am. But I do just…yeah, I feel—I want more people to experience what it’s like when you walk into a math classroom and it’s like, “Hey, this place is for you. You have interesting thoughts about this. Let’s get ’em out.” So that’s awesome. I would love to hear about you and how you…I mean, we have taught different kinds of kids. You know, I taught kids who I think were somewhat set in, they’re a little bit more solid at secondary in who they are as a math learner. Like “I know who math is and who I am with math.” And I’m really excited to hear what your math bio allowed you to do with students who were perhaps open to the idea that they are very mathematical or at least not yet closed off to those possibilities. So, yeah. What are some of the high, the, you know, the high and low water marks of the making of Bethany Lockhart Johnson, math teacher? <Laugh>

Bethany Lockhart Johnson (21:24):

Thanks for asking, Dan. <Laugh> I’ve shared aspects of my math bio because I think it really informs the way that I talk to people about math and think about math. And I like to share it because I want folks to consider their own journey with math, as we like engage with problem-solving and sense-making and thinking about the students in our classroom. My dad is a math and computer science major. So he had a computer very early on. I wish he had invested in Apple early on when he had like one of the first Apple computers ever. And, sorry, dad, but it’s true. I do wish you had done that.

Dan Meyer (22:10):

I’m sure he does too.

Bethany Lockhart Johnson (22:11):

Oh, he does. So math and computers and conversations about counting, you know, it felt like it was kind of just normal. Like it was around me. And I went to Montessori, which is a private school that—oh, they have some public Montessori—but it’s very self-directed. And so we would have these kind of charts, these goals for the day that you explored. And so we would explore math in very, I don’t know, very organic ways, with these natural materials. And I feel like I excelled at math, but it wasn’t something that I was conscious of. It was just like, “Oh, well, yeah. Math, it’s, you know, something we do.” And then when I went to—when I left Montessori in fourth grade, I remember that year being a lot of like repetition. I was like, well, we did this. We covered this. And except for the mission project that we hadn’t done, that was all new. And that’s it. For another time I’ll share about that. But <laugh> then, they actually, I was moved with a group of students to the fifth grade math class, ’cause we had already done the work that we were doing. And so, it wasn’t that it felt like it came easily, but it did make sense. What we were doing made sense. And then it all kind of changed. There was a lot of change in my family. There was, like, missed school time. And we moved and I went to a new middle school and I was in this environment with students who—it was like an accelerated program. And so I was in this environment with students who were pretty competitive with each other. And I remember going—and I was not from of a competitive environment; like Montessori is not competitive. It’s not about that.

Dan Meyer (24:02):

Right. Right.

Bethany Lockhart Johnson (24:02):

It’s—it was very strange to me that I would be competing against anyone, even competing against myself. And I, you know, knew how to set goals. But it was a different level of energy. And I felt like, because I wasn’t competitive in that nature, I felt like that kind—I felt on the outside of a lot of the energy. Besides the regular, like, middle-school feeling outside of things. And I remember the first friend that I made. Hi, Susan! She had said to me, this was like maybe our second week of school, she’s like, “Oh, at lunchtime, come with me to math club.” And I was like, “OK.” And I remember walking into that room and I had no idea what was going on. And so that was one of the first times where I was just like, “Whoa, I have absolutely no concept of what they’re talking about or what.” These are my peers. I felt very—it was very—it was strange. It was strange. I was like, “This doesn’t feel like a space for me at all.” When I think ordinarily I was kind of excited about the idea of going to math club at lunch, you know? And over middle school, I kind of just got progressively more and more behind. It started with missing some work and then missing more and then checking out. And, you know, the problem was that I really made it about myself. That, like, it wasn’t something that I was then good at or could do. When really it was that well, pre-algebra, I was having a really hard time in like the rest of my life. And so I wasn’t real present in that class. And so when I got to algebra, it didn’t make a whole lot of sense. And then if I missed Monday, Tuesday, and Wednesday, well, Thursday is gonna be hard, you know? And, it just got progressively harder and harder. So I had this great idea that between eighth grade and ninth grade, I was going to take this accelerated geometry class. ‘Cause that was the ninth grade class, it was geometry. And I would take it. It was like geometry in three weeks or something. So then when I entered high school, I would’ve gotten this like jumpstart. But I wish I had said, “Oh, I’ll take this, and then in ninth grade I’ll take geometry.” So like I’ve already kind of gotten a preview of the material. But instead I went to the 10th grade math, which was like intermediate algebra, trigonometry. I had absolutely no clue what was going on. And I had a very, very difficult time and I wasn’t ready for that class. But it was exacerbated by the fact that this teacher felt very free to let the freshmen in that class know that they shouldn’t be in that class. That this class was for 10th graders.

Dan Meyer (26:49):

Oh wow. Oh, wow.

Bethany Lockhart Johnson (26:51):

And we had a rather contentious relationship. And I will never forget that we were in the hallway, and he says to me, “You don’t belong here.” And I’ve talked to—I’ve talked to a girlfriend of mine about her experiences with this teacher and she has the fondest memories.

Dan Meyer (27:13):

Wow.

Bethany Lockhart Johnson (27:14):

She—in fact, almost everyone I’ve spoken with, you know, if we are talking about past teachers or, “Oh, what was that class like?” I mean, they just have these wonderful memories! And for me, my sense of like belonging was already so on a tight rope anyway, that to have this adult, this teacher, tell me, “You do not belong here,” just crushed me. And in hindsight, I think he was saying like, “This class is too hard for you.” I mean, maybe. <Laugh> But all I heard was “You don’t belong here.” And I extrapolated it to connect to math and to anything having to do with math in general. And it just got worse and worse through high school in the world of math. My next math class was even—I had to repeat that class, and still didn’t understand what was going on, and felt more out of place, and, you know, it’s one of those things that I just kind of had started to accept that, I guess, math isn’t for me. I guess I’m just not a math person. Or whatever these stories are that I started to create and build and find evidence for around me that was informing that this wasn’t for me. And I had always done well in school. I was in, you know, accelerated classes. I felt like I was capable of problem solving. And yet in math, I just felt like I had all of this evidence saying that I didn’t belong there. And so when I went to college, I took whatever two math classes were—you know, I was in performing arts and then I did ethnic studies as well. And I remember you had to take two math classes that were GEs. There were these classes that if you don’t wanna deal with math, you go take those classes. And I was like, “Oh yeah, I’ll take that. I’ll take that.” The gulf widened, you know? <Laugh> And I didn’t feel like anxiety when I had to do things like balance my checkbook or navigate math in everyday spaces. It was just, it would never occur to me that I would like seek out opportunities to engage with math or think about it or talk about it.

Dan Meyer (29:35):

That is—yeah, that’s just so wild, how, I don’t know, like it’s often, from the student’s perspective, it is them in a vacuum with math, and the two of them interact and decide if, you know, if they’re right for each other. But from the grown-up perspective, it’s just, you know, it’s a little bit clearer that your story with math was not just you in math, but you with, you know, various external things happening. With family, various teachers playing their different roles—sometimes, you know, really tragic and horrible roles—and then like the compounding mathematical debt that it feels like you were kind of building up, as challenges in one year didn’t get resolved and moved into the next year and so on. And all that makes me wonder—it makes me, like really, really scared, first of all, because I would bet that your teacher might not even remember that moment, that for you is part of just a pivotal moment in your math story, and how many kids have I played—have I been a part of their story in that way and wouldn’t even recall? You know what I’m saying? So that’s a scary part. And then also I’m just wondering, like, how can we, how can we help kids who are in those moments recognize that, “Oh, this kid is like absent a bunch,” and give them more resources to be successful rather than say, “Well, you just gotta try harder now.” Those are things I’m wondering, hearing your story. Thank you for sharing that. I’d love to know more about how you then became a teacher and what all that did for you as you helped students.

Bethany Lockhart Johnson (31:06):

Well, but to answer what you were saying, it wasn’t that I wasn’t—I was always absent physically, but at least like mentally at that point, because it had become so difficult. It didn’t make sense to me. So I was just really checked out in math class, you know? So in hindsight, you know, as a teacher, for sure I can look back, and especially hearing these stories and these experiences my friend had with this teacher and just like chalks up as one of like her most favorite teachers ever! And you know, he clearly did a great job for so many students. But for me, and I think for some people, they would’ve taken those challenges and, you know, it would have fortified them in a different way or something. But for me, I took it upon myself to mean certain things about myself and about my ability and what I was capable of. And so I think, I think in some ways, you know, yeah, it’s all, it’s all interconnected. You know, when your students walk in the door, they’re not this—the things that are impacting them in their life are coming into the room with them. And I don’t think we can take that for granted and think, “Well, if they just focus hard enough…”

Dan Meyer (32:21):

Yeah.

Bethany Lockhart Johnson (32:23):

So let’s go back to my love of Oprah. You know, Oprah talks about living your best life. And something I really appreciate about Oprah is that she encourages you to examine, like, sticking points, right? Like she doesn’t just say, “Well, this…just pretend nothing ever happened, and everything’s fine!” You know, she really talks about making time for reflection. And I kind of got mad that anytime I thought about math, or math schooling came up. Or, you know, whatever, any time that came up that I just felt UGH about it. And I felt like a failure. And I’m like, “You know what, what if I took a math class? And I’m an adult at this point. I’ve graduated. I have—I’ve left college. I have my degrees. But I said, “What if I took a math class?” So I went down to, the city college and I found out that you have to take this exam, like a placement exam. And I went and took the placement exam. And I remember it’s one of the responsive tests where if you get it right, the next question’s a little harder. And so I’m taking it, panicking, because it’s getting more like…I just, you know. And I remember it placed me in like, whatever, Algebra Something, this class that was far more advanced than I thought I should be in. And I was like, there’s been a mistake! You know, and I went to the counselor and said, you know, “I got these results, but I couldn’t answer a lot of the questions on the test.” She’s like, “No, no, no, that’s how it works.” So I go take this class and the class was hard. And I decided that I was just gonna keep showing up. And every day before class, I kid you not, they had a little math…it was like a math center where you could go in and they had a bunch of tables and you’d sit at the table and you could sit and do your work or whatever. If you had a question, you walked up and put your name on a clipboard and then somebody would come and help you. So I did that, every single—like before every single class I would go in. I’d sit there. I’d do the work. I’d go. And I’d get help. Like somebody would walk over and you know, some kid for whom they’re like this…you know, they’re math—it might be you, Dan! It could be you! It could have been you! You know, would walk over and be like—

Dan Meyer (34:38):

Yeah, I was in Help like that. Naw, it’s awesome. Love, love those people. Yeah.

Bethany Lockhart Johnson (34:42):

And you know, I did it. And I did so well in the class. I did exceedingly well in the class. And I said—

Dan Meyer (34:50):

Take that! Take that, everything! Every other math experience!

Bethany Lockhart Johnson (34:53):

I said, what?

Dan Meyer (34:55):

Yeah!

Bethany Lockhart Johnson (34:55):

Wait a second.

Dan Meyer (34:56):

Yeah.

Bethany Lockhart Johnson (34:57):

And it was that I was present. I was not afraid to look at what didn’t make sense. And if something didn’t make sense, it didn’t mean there was something wrong with me. Whaaaaat?

Dan Meyer (35:10):

Yeah. Yeah.

Bethany Lockhart Johnson (35:10):

So I was just in such a different space. And then I took another math class and that class was even harder. And I did the same thing where I went to the little lab and, you know, and it just buoyed me. And it made me realize that, like, this story, that my experience with it was very powerful and that was a real lived experience, but that it didn’t have to define my relationship with math. But then! I decided I wanted to go back to school to become a classroom teacher. And I totally—this was a couple years after that math class experience. So now, you know, I’m healing my relationship with math through basic positive experiences, da, da, da, you know, doing other work. But fast-forward, for a whole number of reasons, decided to become a classroom teacher. And I freaked out. All of my—like, I’m studying for the GRE and the CSET and all the things you have to the hoops you have to jump through to apply to the masters program and the credential program. And I freaked out. I was so close to quitting, Dan. Because I was convinced that the reason I couldn’t be a classroom teacher is because I wasn’t capable in math. Like I was—it was all that resurfaced. And even though I now had evidence to say something different, to the contrary, it was still so visceral. And I was so scared. But I passed that Math CSET.

Dan Meyer (36:47):

Get it.

Bethany Lockhart Johnson (36:47):

I did well enough on the GRE—

Bethany Lockhart Johnson (36:50):

Yes!

Bethany Lockhart Johnson (36:50):

You know, I finished my credential. I worked really, really hard. I had to work so hard in my student placement, when I was student teaching for a fifth-grade class, ’cause I felt like, “Oh my God!” I mean, now I could do the mathematics, but I couldn’t TEACH it to someone, you know? But I had amazing professors at UCI, and my math professors really like just—and my mentor teacher! shout out to Jennifer! shout out to Phil!—these amazing mentor teachers who just loved teaching and who loved—like you said, you have these teachers in your life who you got to see the way that they listened to students. They taught me about that love of listening to students. And then I fell in love with, you know, CGI, cognitively guided instruction, and started learning all about all of these educators who just wanna learn from students’ thinking. And it was just so powerful. And I realize as a kindergarten teacher that I have this really special role in helping to create space for a positive school experience. Like we get to talk about—I talk about my students as mathematicians; they’re writers; they’re thinkers; they’re problem-solvers. And I also want to make space for parents. Some of them, this is their first kid in kindergarten, and they brought all of their experiences, a lot of it negative, that they had had with mathematics. So I felt like it was such an exciting opportunity to help show parents how they could have conversations about math with their students. That also, I hope helped heal their own anxiety with mathematics.

Dan Meyer (38:41):

Right, right.

Bethany Lockhart Johnson (38:42):

Like, I’ve not even scratched the surface of math learning. But I just have such a changed perspective and relationship with math. And I just fell in love with the sense-making. And I fell in love with the journey of it. I still experience math anxiety about a wide variety of things, but I do love it. And I feel like there’s a space for me in relationship with math. And that really excites me.

Dan Meyer (39:09):

Yeah. Wow. Listen to that folks. We, we don’t deserve her! Bethany Lockhart Johnson! She got some math game and could have gone off there and, you know, become an accountant or something. And she chose to hang with kids and their parents. That’s so wild that you’re like rehabbing parents and their self-conception about mathematics at the same time. I think that is so cool.

Bethany Lockhart Johnson (39:32):

Well, thanks Dan Meyer. I gotta tell you, I don’t know when or if I’ve ever shared that much of my math story. So there is a certain amount of vulnerability there. But thanks for listening. And I’m glad that, you know—I think there’s space for us to talk about these things that we care deeply about, but that can be really complicated.

Dan Meyer (39:56):

Yes. Yes. And I love how you you’ve really sharpened the point on what I feel like I know in my brain, but not my body all the time: That individual teachers are huge. Like, individual teachers, and individual moments of teaching, are just not something to play with. You know, like that kid that’s in fifth grade having a tough time, like there could be a month or a day-long period where all of a sudden, like, you’re just like, “Oh yeah, I’m back in the mix; like, me and math are still buddies.” And there’s also like moments that you had, where like one casual word from a teacher can just really put a huge wedge between you and a discipline that needs and wants you and your intellect in it.That’s a really powerful testimonial. Not just for math, but for teaching, your teaching bio.

Bethany Lockhart Johnson (40:43):

I agree with you. And I also, I also…you know, I think we can’t put this—we are human. Teachers are human. And so I’m sure there’s things I’ve said to students. Twenty-second story: a student stapled his finger in my class. <Laugh> And I remember holding his hand and saying, “Why did you do that?” And I wasn’t yelling at him, but it was like, I am sure the panic in my face…like, that’s what he’s gonna remember about kindergarten. Right? <Laugh>.

Dan Meyer (41:19):

Yeah.

Bethany Lockhart Johnson (41:20):

That. He will remember that. He won’t remember the really cool city project we did. He’s gonna remember his teacher holding his hand, in his face: “Why did you do that?”

Dan Meyer (41:30):

Yeah. Yeah.

Bethany Lockhart Johnson (41:30):

You know, so we’re human. And yes, it was awful that that teacher said that to me. There were a thousand other ways that he could have said whatever it was he was thinking. And that did deeply wound me. But despite his influence—because teachers do have a lot of power and I think they need to examine that power, ongoing—it still doesn’t have to define us. So I don’t wanna put this pressure, like—

Bethany Lockhart Johnson (41:55):

Sure.

Bethany Lockhart Johnson (41:56):

“So never ever say anything negative!” You know, we’re human.

Dan Meyer (42:00):

I feel like that kid is currently on some office-supply podcast talking about “your office-supply bio” and saying, “Let me tell you how I first got really freaked out by staples. Here’s the deal: I only use paper clips. And here’s why.”

Bethany Lockhart Johnson (42:15):

“Here’s why.” But then—callback!—he’s going to stumble upon THIS podcast and think, “And because I’m so adept with paper clips, I can beat that record!”

Dan Meyer (42:30):

Though—aaay! whoa! Settle down!

Bethany Lockhart Johnson (42:31):

BOOM.

Dan Meyer (42:31):

Don’t get any ideas, kid. No way. Uh-uh. I don’t like that at all. That’s not what—that’s not what I want to have happen here. No, thank you.

Bethany Lockhart Johnson (42:41):

Well, I’m spent, Dan. I need a nap.

Dan Meyer (42:45):

Yeah. I need a box of Kleenex. I need a nap. I need a—yeah, for sure, a baba. Uh-huh. Definitely. Hey, so look, I’m not expecting you folks out there in the lounge to kind of give us the same depth or breadth. You know, we are here, of course, for your entertainment. Feast on our stories and dramas. But I would love to know at some point, like, what are a few, a few moments that really came to define you mathematically? Came to influence you as a teacher? I think we would do really well for each other to understand that about all of our processes. So yeah, I would just toss in a plug in for Twitter, @MTLShow, or Facebook, Math Teacher Lounge; it would be fantastic to hear from you.

Bethany Lockhart Johnson (43:24):

Thanks so much for listening.

Dan Meyer (43:25):

Thanks, folks. Bye now.

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What Dan Meyer says about math teaching

“Teaching, more than other professions, is a generational profession. The kinds of joyful experiences we offer, or don’t offer, now affect the experiences students that haven’t even been born yet will have years later.”

– Dan Meyer

Meet the guests

Dan Meyer

Dan Meyer taught high school math to students who didn’t like high school math. He has advocated for better math instruction on CNN, Good Morning America, Everyday With Rachel Ray, and TED.com. He earned his doctorate from Stanford University in math education and is currently the Dean of Research at Desmos, where he explores the future of math, technology, and learning. Dan has worked with teachers internationally and in all 50 United States and was named one of Tech & Learning’s 30 Leaders of the Future.

Bethany Lockhart Johnson

Bethany Lockhart Johnson is an elementary school educator and author. Prior to serving as a multiple-subject teacher, she taught theater and dance and now loves incorporating movement and creative play into her classroom. Bethany is committed to helping students find joy in discovering their identities as mathematicians. In addition to her role as a full-time classroom teacher, Bethany is a Student Achievement Partners California Core Advocate and is active in national and local mathematics organizations. Bethany is a member of the Illustrative Mathematics Elementary Curriculum Steering Committee and serves as a consultant, creating materials to support families during distance learning.

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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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S5-05. Math technology & hacks for math anxiety: research-based tips for caregivers

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We’ve been very lucky to have so many prolific and brilliant researchers on this season of Math Teacher Lounge, and our next guest is no exception.

Listen as we sit down with Dr. Marjorie Schaeffer to discuss what causes math anxiety, math hacks, and how the right math technology can make an incredible impact in children and caregivers coping with math anxiety.

Listen today and don’t forget to grab your MTL study guide to track your learning and make the most of this episode!

Download Transcript

Marjorie Schaeffer (00:00):

I think the most important thing we know from literature right now is that high math-anxious parents, when they interact with their children, their children learn less math over the course of the school year.

Bethany Lockhart Johnson (00:12):

Welcome back to Math Teacher Lounge. I’m Bethany Lockhart Johnson.

Dan Meyer (00:15):

And I’m Dan Meyer.

Bethany Lockhart Johnson (00:16):

We’re onto Episode 5, Dan, of our series on math anxiety. And I wanna say it feels so lovely to imagine all of these people out there doing work to help combat math anxiety. I dunno, it just makes me feel excited about the possibilities. This work is out there; it’s happening! Kids and teachers and caregivers are being impacted by these conversations. Not just — I mean, I don’t just mean the conversations we’re having on Math Teacher Lounge, but I mean, that these researchers are doing. Like, yes, we can change this!

Dan Meyer (00:53):

This is great. Yeah. We have people who are extremely smart, who have dedicated their professional lives to studying math anxiety and resolving it. And each of them that we’ve chatted with — they share lots of ideas in common, but I’ve loved how they each have their own different flavor or take or area of emphasis on a problem that hits everybody everywhere. It’s in your home, with kids and caregivers. It’s in schools. It’s in our places of teacher preparation and professional learning. Every place is a place where we can focus on resolving issues of math anxiety. It’s exciting.

Bethany Lockhart Johnson (01:26):

Yeah, I feel like … if there could be a course in — we all know that our teacher prep programs, in MOST teacher prep programs, there’s not nearly enough math methods or time to cover <laugh> — it’s like ready, set, go! And depending on who your mentor teacher is or what your math methods course … I mean, it can totally shape the way that you are prepared or really not prepared for going out there to teach math! And so I love that we’re having these conversations.

Dan Meyer (01:55):

What I love about today’s conversation is, one, it’s got a little bit of a technology flavor, so there’s that. But I also love, it’s got one of my favorite features about change, which is that it focuses on change to action, change to routine, rather than change to belief. Rather than saying like, “OK, everybody! Everybody stop thinking bad beliefs about math and transmitting them to your kids!” Instead, it says, “What we’ll do is just, hey, we’ll set that aside for a second and we’re gonna do a certain thing every day and watch as those actions make your beliefs change.” That to me is extremely cool. And I think it has a higher likelihood of success than just, like, me telling parents, “Hey, stop thinking these thoughts!”

Bethany Lockhart Johnson (02:37):

“Ready, set, stop being anxious!”

Dan Meyer (02:39):

Exactly. Exactly. So it’s an exciting conversation we’re gonna have here.

Bethany Lockhart Johnson (02:43):

Right. So it’s not a, you know, “wave the wand and all of a sudden, you’re not anxious about math anymore.” But these incremental changes, these incremental conversations, this validation, can really, really impact change. I’m with you on it, Dan. I hear what you’re saying.

Dan Meyer (03:01):

To help us talk through all of these ideas and more, we’re joined by Dr. Marjorie Schaeffer, Assistant Professor of Psychology at St. Mary’s College in Indiana.

Bethany Lockhart Johnson (03:10):

Enjoy. <Jaunty music> So, yes, Dan, we are so excited to welcome Marjorie Schaeffer. She’s Assistant Professor of Psychology at St. Mary’s College. Dr. Schaeffer, we’re so excited you’re here. Hello!

Marjorie Schaeffer (03:28):

Thank you so much for inviting me.

Dan Meyer (03:29):

Yeah. We are super-lucky to have had so many prolific and brilliant researchers about math anxiety on our show. You’ll be no exception. And every time, we love to find out about how you came to study math anxiety, which winds up being a really interesting glimpse into your backstory bio. So tell us, what is the route by which you came toward studying math anxiety?

Marjorie Schaeffer (03:51):

Oh, I love that question. I’m really interested in how the attitudes and beliefs of parents and teachers influence children, especially around math. And I actually became interested in this idea in college, when no Child Left Behind was actually first starting to be implemented in schools with high-stakes standardized testing. So much so that I actually did my thesis on this thinking about, “Do children understand the importance of high-stakes testing? Do they have anxiety around that idea?” And so that was really my first foray into the anxiety literature. And that was kind of the entry point into math anxiety for me.

Dan Meyer (04:28):

So you started by studying a very high-stakes assessment, like our students connecting with this. And the assessment is once per year. And classroom instruction is every day. So how did you move from the assessments to the everyday instruction?

Marjorie Schaeffer (04:44):

That’s a great question. So, after college, I actually taught kindergarten. And so from that, I saw the day-to-day impact of instruction and the day-to-day impact of children’s individual attitudes and beliefs. And so I really became interested in thinking about, “How do we understand why some children are really successful from the instruction happening in classrooms and why other children need a little bit more support?” And so math anxiety was one way for me to really think about the individual differences I saw in my kindergarten classroom.

Dan Meyer (05:18):

It feels like you headed … you went farther upstream, is what it feels like. Where assessment … there’s like some kind of anxiety around assessment, let’s say. And then you ventured farther up the stream to classroom instruction and then still farther into kids’ homes. It seems like your research invokes a lot of curiosity about the sources of a kind of amorphous, flowing phenomenon called math anxiety. And I’d love to hear a bit about what you know about how caregivers transfer, transmit — whatever the word is — math anxiety to their kids.

Marjorie Schaeffer (05:55):

For parents … we think that the attitudes and beliefs of parents matter. And we see that for lots of areas, not just math anxiety. But I think math anxiety, we see that really clearly. And so, we can think about it both in terms of what kind of input parents provide. So, how do families talk about math with their children? What kind of support do they provide around homework? And those are ones that I think are a little obvious. But we can also think about the offhanded comments that parents say to children when they’re talking about math generally. Right? So, we see lots of memes going around, talking about how hard math homework is. And so, I think when parents say offhanded comments like, “I’m not a math person,” or “We’re just bad at math,” that communicates values to children. I think the most important thing we know from literature right now is that high math-anxious parents, when they interact with their children, their children learn less math over the course of the school year. And this specific mechanism by which that happens is still an area for a lot of research. And so some people think it’s about input. So maybe if I’m math anxious, I’m avoiding math. And so, when I have an option to read a picture book that has math content, I focus on the colors instead. And so, my child is actually getting less math than other children. We can also think it’s about these messages that are provided. So, when I talk about math, I send the message to my child, it’s not for them, and therefore the child wants to engage in it less. And some of my work looks at things like expectations and values. So, thinking about, “Do math-anxious families actually value math less than other families unintentionally?” And so, we have some support for this idea that they expect less of their children. And so maybe when they struggle, they respond in different ways than a family who’s lower in math anxiety.

Bethany Lockhart Johnson (07:53):

This is so fascinating to me. I also was a kindergarten teacher. And I remember a mom who just … she had such like palpable math anxiety. And during one of our conversations, she was talking about these homework sessions with her daughter. And I may have mentioned this on the podcast before. But she was talking about how every night they would sit together and they would do all this math. They’d do, like, extra math together. And it always ended in tears. And despite her math anxiety, she didn’t want her daughter to experience the math anxiety that she did. So she was trying to pile it on, so her daughter was more proficient and comfortable. And instead, it was perpetuating this anxiety about it. And so, it’s a phenomenon then, right? Even if a parent is saying, like you said, maybe completely unwilling, this mother was actually trying to do the opposite. She was trying to help, you know, imbue the love and comfort with math. Right?

Marjorie Schaeffer (09:01):

Absolutely. This is why I think in my research, it’s really important that we find low-stakes, low-stress ways for high math-anxious families to do math. They absolutely can support their children in doing math. But they need a little support. We want it to be a fun, low-stakes environment, right? So maybe that’s the connection back to high-stakes testing, that I want children to have fun math experiences.

Dan Meyer (09:28):

Yeah. This is challenging, because it feels like the more caregivers know about math anxiety, and its pernicious effects on students, and how easily transmitted it is, one could become quite anxious about math anxiety. And, you know, no one makes great decisions when they’re anxious. So if I’m recalling our various episodes we’ve done, we’ve heard from people say, “Well, you need to validate students’ math anxiety. This is not something to just ignore or brush past. But also, not validate it in a way that says, you know, ‘This is OK and generational and inevitable.’” Which presents parents with a very thin path to follow, it seems like. So I love what you’re saying about how we gotta just de-stress the whole process.

Bethany Lockhart Johnson (10:11):

You’re avoiding the whole, “I wasn’t a math person either” kind of thing. <laugh>

Dan Meyer (10:15):

Right, right, right. Yeah. So I’d love to know more. We’re excited about the technology that you have studied and helped develop, presumably, called Bedtime Math, anapp for caregivers. And I’d love to know more about what that is and what it offers parents who know enough about math to know that they don’t want to transmit math anxiety to their children, but also want to support. So what does that offer them?

Marjorie Schaeffer (10:39):

So Bedtime Math is an app. It’s freely available on iTunes or the Apple Store or Google Play. And what it’s designed to do is to provide a nightly topical passage. So one of my favorites is the one about Groundhogs Day. And so it talks a little bit about the history of Groundhogs Day, and then it asks math-related follow-up questions. So starting at a preschool level, going through late fifth grade. And it’s really meant for parents to pick the one that meets their children where they are. And so the preschool-level question asks children to pretend to be a groundhog and walk to the left and walk to the right. So a skill that families might not think about as being math, but we actually think that IS part of understanding math. Understanding left and right directionality. And then the next question can ask questions like, “If it took the groundhog three seconds to climb out of the hole, and then two more seconds to see its shadow, how much time did it take all together?” So a simple addition problem, but it’s phrased in a fun way. And so the hope is that for high math-anxious families, these interactions are fun and playful. They don’t look like fights over homework. They’re just conversations that families can have around topics that are naturally interesting to children. And our hope is that when families have lots of these positive low-stakes interactions, they actually can see that we can talk about math in unstressful ways. In lots of ways, right? We can also do this at the grocery store. We can also do this while we’re cooking in the kitchen. It doesn’t just have to be fights over homework.

Bethany Lockhart Johnson (12:14):

And I actually have the Bedtime Math — one of the Bedtime Math books. And I was so excited to find out that there’s an app. And I think one of the things that I loved about the book is that these are invitations, right? They’re exactly that. Low pressure <laugh>, and they’re invitations to have a conversation. And if we were just to tell parents, “Oh, just count!” or, “Hey, just count wherever you go!” You know? No. It’s, in a way, I think, like you said, it’s retraining the parents on what math could look like. Like, “Oh, I didn’t even think we could just kind of have this conversation and we’re actually doing math together.”

Marjorie Schaeffer (12:55):

Yes, absolutely. I absolutely agree. We want it to be fun and playful and not stressful. And we want it to also be things that are meaningful to children’s lives. So these are topics children are interested in. It’s not that we are using flashcards or making children practice math facts over and over again. These are things children should wanna do that can naturally fit into a child’s routine. So almost all families read books before bed, and what we hope is that math can also be a part of the nighttime routine.

Dan Meyer (13:27):

There’s something really subtle here going on that I just wanna name and ask a question about. First of all, it’s cool that you started with studying high-stakes stuff and now you are developing low-stakes stuff. And I’m really curious what makes a thing low-stakes? Like, a few things I’m hearing from you is that there’s, like … I have a small child that I read literature to on a nightly basis. And I feel very anxiety-free doing that. And it’s almost as though, because each of the — tasks is the wrong word for this, but experiences — involve some reading, it puts me, the parent, in a mode that is comfortable and familiar to me. I’m curious: Are there other, as you design, what, one per day for a year? All these different experiences. What are some of the principles that you lean on that help make a thing low-stakes for kids and for parents?

Marjorie Schaeffer (14:17):

Yeah, that’s a great question. So one thing we wanted to be really intentional about is that our app doesn’t look like a lot of traditional apps. There isn’t noises that go off. You don’t enter an answer. And so one of the things that we thought made it low-stakes is that while there is a right or wrong answer — there is a correct answer — we aren’t giving children upsetting feedback. Instead, what we wanna encourage families to do is, if you struggle to remember how many seconds it took the groundhog to come out of the hole, you can work through that with a parent. So it doesn’t feel like you’re getting negative feedback; you’re being told you’re bad at math; you did it wrong. Instead, you’re just getting natural support moving forward. And so that’s one thing we wanted to be really intentional about, was that it wasn’t going to be a negative experience for children. And we are trying to build on all of the positive interactions families are having around nightly book reading. So many ways this can look very similar. You get to read another story that’s topical and hopefully interesting. And then do these little questions together. And so for a lot of families, their children don’t actually really look at the question. It almost feels like the parent is just asking them on their own. Like, they just came up with it. They just wanted to know what would happen to the groundhog. If there were three more groundhogs? How many groundhogs would we have all together? Not like it’s gonna be like homework or other parts.

Dan Meyer (15:38):

So my understanding is that there isn’t a blank into which people type a number in, press “submit” for evaluation, receive the red X, the green check. That’s a key part of the design here.

Marjorie Schaeffer (15:50):

Yes, absolutely. And for research purposes, we would’ve loved to know what families were saying. But we think it’s really important that it’s fun, interactive, that families are working together to get to the right answer, that it’s not a test for children.

Bethany Lockhart Johnson (16:03):

In your research, when you were — maybe you could walk us through the study a little bit. But I’m also curious if you heard from parents that it was carrying over beyond the bedtime routine. Because I would imagine, if I am building these skills and reading these questions and learning that I could talk to my kid like this about math in a fun way, that’s gonna happen then, like you said, when I’m in the grocery store. Or when I’m waiting in line for at the bank. Or whatever, you know? People go into banks now still, right?

Marjorie Schaeffer (16:35):

Yeah, absolutely. So in our study, we recruited almost 600 families and we randomly assigned them. So they had an equal chance of getting both our math app and what we call our control app. And that’s really just a math app without the math. We think of it as a reading control app. And that’s because we wanna make sure that families are having a similar experience, that it’s not just that having high-quality, fun interactions with your child is actually impacting children’s math achievement. And so what we then did is followed those children over the course of early elementary school. And so we worked with them in schools in the fall and spring of first, second, and third grade, really to look at their math learning. And so what we find is that children of high math-anxious adults, when they have the reading app, so what we think of as what’s happening in the real world, we see that really classic gap between children of high math-anxious adults and children of low math-anxious adults. So if you have a high math-anxious parent, you’re learning about three months less math over the course of first grade. But for children who receive this math app, we see this gap as closed. Those children look no different than a low math-anxious parent. And so that’s leading us to think that we’ve helped families talk about math in fundamentally different ways. We did a little bit of just talking to families to see a little bit about what might be going on. And a lot of families do report exactly what you’re describing, where they say this did help them talk about math in different ways they were doing it other times.

Dan Meyer (18:10):

That’s a really extraordinary study design. I don’t know … I love that you folks gave the control group not nothing. Like it’s possible that just parents and kids bonding over a thing regularly would be enough to provoke some kind of academic gain. But you gave the control group a thing that had them interacting socially, bonding, and still this large common gap between high-anxious and low-anxious parents, their kids shrunk together. Is that what I’m gathering here?

Marjorie Schaeffer (18:41):

Yeah, absolutely. So we’re basically seeing we can no longer, when we look at children’s data, say that parents’ math anxiety explains individual differences. So these children look really similar. They’re learning more than children who has a high math-anxious parent and just got our reading control app.

Dan Meyer (19:01):

just diving into the study a little bit more here, what is the time commitment? Or, did you guide parents to say, “All right, we’re gonna do this do this delightful story about a badger for an hour”? Or did people do it for five minutes? And what was the time commitment, roughly, for people?

Marjorie Schaeffer (19:17):

So we tell families to do it however they see fit. Because it is an app, we are able to get some sense of how long, and we are talking about three to six minutes for many families. For a lot of families, they’re reading a paragraph, the paragraph and a half, and then answering one or two questions. They’re not going through every possible question. They’re just doing a little bit, really meeting their kids where they are.

Dan Meyer (19:39):

Roughly how many times per week was that?

Marjorie Schaeffer (19:41):

So we asked families to do it as much as it fit. But we’re seeing about two and a half on average in the first year. And so families are fitting it in a couple of nights a week. It’s not every night.

Bethany Lockhart Johnson (19:52):

So what it sounds like you’re saying is what really was powerful about this app is that it was the space and time and prompts between the caregiver and the child, that chance to really sit down and have some of these meaningful and positive math interactions. How did it shift those relationships?

Marjorie Schaeffer (20:12):

So one of the things I think that makes the app effective is the changing of expectations. After a year, families are really using the app a lot less. And I think that’s OK, that they have found other ways to incorporate math into their lives. And we find that we don’t see an impact on their math anxiety, that they aren’t becoming less math anxious from this experience. Which I think makes sense, because they have had a lifetime of math anxiety. But we do see a change in parents’ expectations and value of math. So they expect their children will be better at math, and they also report that math is more important in their children’s lives. And so I think that’s an important part of it, which is, we can change these values for families, even if we aren’t able to change the math anxiety of the adults in children’s lives.

Bethany Lockhart Johnson (21:01):

I want to for a second before — because I’m loving this idea of the app, and I’m excited to find out more ways to cultivate these conversations in my home and also share this with other folks. Because even folks who don’t even maybe realize they have math anxiety … like you said, so often it’s unconscious. So often we’re putting these little snippets into our everyday conversation, like, “Oh yeah, I’m not a math person.” And we don’t even realize how much is impacting our kiddos and ourselves, right? So I am really curious: What do you think … in your research, what were some other takeaways that you feel like are really strategies that we can think about for combating math anxiety in general?

Marjorie Schaeffer (21:47):

So I’m particularly interested in thinking about how math-anxious adults can help tone down their anxiety so that they can have high-quality interactions with their children, that they interact with. And so one of the big takeaways for my research, I think, is that math-anxious families can help their children with math. They just need support. And so I think there are lots of ways for that support to look like. One, I think it can be an app, but I also think reading a little bit about math can be really helpful. So it’s not new. So the first time you aren’t thinking about some of these ideas is as your child has their homework open in front of you. And so you can process your own feelings separately before you have to do it with a child. I also think reminding parents that math is everywhere and that math is actually lots of things that we all love to do. Math isn’t just calculus. Not that calculus isn’t wonderful. But that math is measuring, math is counting ducks at the park. Math is talking about how many times did I go down this slide. And talking about math in this way, I think reminds families that they are great at that. That even if maybe they’ve had bad math experiences before, they can do math. Especially the way their preschool or early childhood, early elementary school student needs them to. And I think that can then set the foundation for being really successful later.

Dan Meyer (23:13):

So is your research then, your subsequent studies, your line of inquiry, is moving more towards how to support parents, then? Is that what I’m hearing?

Marjorie Schaeffer (23:22):

Yeah. So I’m really interested in both understanding how the math anxiety of parents and teachers influences children. And so math anxiety is really common and we know that it’s particularly common in early elementary school teachers. And so it’s very likely that children are interacting with a highly math-anxious adult. And so I’m really interested in thinking about how we can support those individuals in doing it. And so both, I think, things like Bedtime Math, which provide fun, unscripted ways to do that, but I’m also interested in the teacher equivalent. So, thinking about whether having things like a math coach can help teachers have more positive experiences with math. So if you see someone else play math games with your students, can that help you do it as well?

Dan Meyer (24:09):

It makes me wonder a lot about an app for teachers or an app for parents, one that’s not designed to be co-consumed with kids and their parents. But what that would look like … yeah, that’s really interesting.

Bethany Lockhart Johnson (24:21):

If we have a parent who, let’s say they have a third grader, fourth grader, fifth grader, or a middle schooler, right? Outside of early education. And they say, “OK, but what do I do? I’m with my kiddo; I don’t remember this math.” And they’re realizing that their anxiety may be influencing their kiddos’ disposition of mathematics, Or maybe they’re just in the midst of the battle <laugh>. What would you say to those folks, especially if it’s math that maybe they’re not comfortable with?

Marjorie Schaeffer (24:56):

One, I think we should like tone down the stress, right? Remind ourselves that it’s homework and homework feels really high-stakes, but these other outcomes are really high-stakes too, right? And so I’m really interested in the idea that can we help parents feel more comfortable about math by watching their own children teach it to them. So what’s a concept that the fourth grader actually feels really good about? And can they remind their parent how to do it? Can, together, they problem-solve the math homework? And so it’s not just on the parent to give the child the right answer. We know that’s a recipe for communicating some negative things about math. But instead, help the parent-child pair figure it out together. So what are some resources we can do? Can we look it up on the internet together? Can we write an email to the teacher together? Can we think about what are other problems that maybe we know how to do, and therefore we can use that same model here? So I want parents to feel like they are not solely responsible for it. That they can help figure it out with their child together. And so it’s a fun interaction.

Bethany Lockhart Johnson (26:02):

I love that. I love that.

Dan Meyer (26:03):

Yeah. Yeah. That’s wonderful. Yeah. A conviction that I have, and I think it’s true, is that any math that we’re learning at middle school, the attraction can be dialed down to a degree that a very small child, or a parent who has a very small child’s understanding of math, can appreciate. So instead of calculation, estimation. Instead of proof, just make a claim about something. And it makes me wonder about a companion to the work that’s happening in schools that parents feel inadequate to support, that students might not want to teach their parents. But which they could both, on a daily basis, say, “Here’s a way we can engage in this at a level that is comfortable to both of us.” Just dreaming out loud here. No question asked. No response needed. I just love your work. And made me wonder about that. Can you let me know your thoughts about technology? It is very rare that we have someone on the call who is an academic and very well-versed in research, but who also is published not just in in papers and textbooks, but also in digital media. It’s consumed by lots of people. So I am trusting that you have opinions about how math looks in technology. And I wonder if you’d offer some thoughts about how it goes, right? How it goes wrong from your own eyes.

Marjorie Schaeffer (27:14):

OK. That’s a great question. I think that we need more research. I first wanna say that I think that technology has really exploded in the last few years. How children have access to technology and screen times has really changed. And what we need is high-quality research happening. That said, I think that all of the things we know from child-development research still apply to technology. And so we know that children learn best when they are engaging in interactions with their parents. And so when families can use technology together, or at least can talk about what’s happening, it can be really effective. I also think technology, especially math apps, are best at teaching concrete skills with very clear answers. So I think practicing math facts is a great use of technology. So I love that Sushi math app where you solve multiplication problems and then get to quickly pull the sushi off the cart, right? But for higher-level questions, where we’re thinking about word problems or where what we’re helping to teach students is complex thinking, apps have a harder time doing that. Because students can often figure out the answer without engaging in the thinking that we are hoping that they’ll learn. And so I think technology absolutely has a piece. I think technology is helpful for parents. I think the logistics of helping parents live their lives is a good reason to use technology. But I think we need to be conscious of what it’s replacing. And so I think a world in which we think fourth graders can learn math only from apps is not realistic. But absolutely apps can be a great supplement to what’s already happening in the classroom.

Dan Meyer (28:56):

Yeah, that’s super-helpful. We have done a lot of work in digital curriculum here at Amplify, and often face the question on a daily basis, “Should this math be digital or on paper? Should we have the students stand up and talk or type something?” And those decisions are way too crucial and way more sensitive than a lot of the app-based education gives credit to. So appreciate your perspective there.

Marjorie Schaeffer (29:22):

OK. And I don’t think there’s one answer, or one answer for all classrooms. I think it’s like always a balancing act. I do think that one of the reasons our work is successful is because the parent-child interaction. And we want parents to learn from these experiences. And I think the same thing is true for for teachers.

Bethany Lockhart Johnson (29:41):

Dr. Schaeffer, thank you so much for being with us today and for sharing about your research, and again, for inviting us to reconsider ways that we can develop a more positive relationship with math. And that parent or caregiver or teacher relationship with a child, we’re seeing just how incredibly impactful that is. And I really appreciate your work and your voice on this. Thank you so much for your time.

Dan Meyer (30:07):

Thank you.

Marjorie Schaeffer (30:08):

Thank you for having me.

Bethany Lockhart Johnson (30:12):

Thank you again, Dr. Schaeffer, and thank you all for listening to our conversation. You can check out the show notes for more on Dr. Schaeffer’s work and to see a link to the app that we shared about Bedtime Math.

Dan Meyer (30:25):

Please keep in touch with us on Facebook at Math Teacher Lounge Community, and on Twitter at MTLShow.

Bethany Lockhart Johnson (30:32):

We would love to hear … you’ve been listening to this series; we’re dipping our toe into all these aspects of math anxiety. Is there something that you’re still wondering about? Something you wanna share about your own story with math anxiety?

Dan Meyer (30:43):

And if you haven’t already, if this is your first exposure to the Math Teacher Lounge podcast, please subscribe to Math Teacher Lounge, wherever you get your fine podcast products. And if you like what you’re hearing, please rate us! Leave us a review. You’ll help more listeners find the show.

Bethany Lockhart Johnson (31:01):

And let a friend know. But you know, it’s, it’s nice and cozy here in the Lounge, right? There’s no pressure. We’re hanging out. It’s all about learning. We’re learning together. We’re glad you’re here and we want others in your community to join us in the Lounge as well. You can find more information on all of Amplify’s shows at our podcast hub. Go to amplifycom.wpengine.com/hub. Next time on Math Teacher Lounge, we’re gonna be chatting about where we are today that we weren’t a few months ago in this topic.

Dan Meyer (31:31):

We’ll be chatting about this last series about math anxiety, and trading our favorite insights and observations from the run of the season.

Bethany Lockhart Johnson (31:41):

I just love this series, Dan. And thanks, all, for listening. We really appreciate having you in the Lounge.

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What Marjorie Schaeffer says about math

“We want it to be a fun, low-stakes environment, especially in high-stakes scenarios like testing. We want children to have fun math experiences.”

– Marjorie Schaeffer

Assistant Professor of Psychology at Saint Mary’s College

Meet the guest

Marjorie Schaeffer is an assistant professor of psychological sciences at Saint Mary’s College. She received her Ph.D in developmental psychology from the University of Chicago. Marjorie is interested in the role parents and teachers play in the development of children’s math attitudes and performance. She is specifically interested in the impact of expectations and anxiety and on children’s academic performance. Her work has been published in outlets including ScienceJournal of Experimental Psychology: General, and Developmental Science.

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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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S5-04. Coaching tips for managing math anxiety in teachers

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So far this season, we’ve investigated math anxiety in students and its causes with passionate researchers and curriculum experts, including one from Sesame Workshop! Now we hear from Dr. Heidi Sabnani, consultant, coach, and co-host of Math 4 All, as she gives us research-based tips for teachers who are facing math anxiety themselves! Listen as we discuss Heidi’s own math anxiety and journey through math, the effects teacher math anxiety can have on instruction, and practices educators can implement right away for overcoming math anxiety.

Listen today and don’t forget to grab your MTL study guide to track your learning and make the most of this episode!

Download Transcript

Dr. Heidi Sabnani (00:00):

Coaching is the opportunity to provide that just-in-time kind of professional development for teachers, if we go at it in a slightly different way.

Dan Meyer (00:10):

Hey folks, welcome back to Math Teacher Lounge. I’m your host, Dan Meyer.

Bethany Lockhart Johnson (00:14):

And I’m Bethany Lockhart Johnson.

Dan Meyer (00:16):

Bethany, how are you doing, and how are you feeling about our current trajectory through this exploration of math anxiety?

Bethany Lockhart Johnson (00:24):

Dan, I gotta tell you — let me make it about me for a second. <laugh>.

Dan Meyer (00:29):

Go. Do it.

Bethany Lockhart Johnson (00:30):

If only I had known that so many other people experienced math anxiety, and I wasn’t the only one. I mean, I’ve said it before, but you know, I hope that this series so far is helping to reframe math anxiety for folks who maybe have a narrow definition of it … and I guess expand, reframe. And also, for those folks who are working with students who have math anxiety, or who they themselves have experienced math anxiety, I hope they’ve found some tools, some resources. Right? Like, “Yes!”

Dan Meyer (01:04):

Yes! Same.

New Speaker (01:06):

And what about you? How are you feeling?

Dan Meyer (01:08):

Yeah, I hope this has been cathartic for all of our listeners who have experienced math anxiety, and not re-traumatizing, that there are lots of people who feel this way about math in particular. And that it’s so well-experienced, so broadly experienced, that people have decided to study it a whole bunch. Which is great. And now we’re moving into our kind of solutioning. You know, in my relationships, I’m sometimes told that I rush too quickly to solutions before trying to understand what’s going on. So I’ve loved our episodes that have been about what is going on. And now, with Dr. Truglio last episode and our guest today, we’re moving more into some solutions, which I’m excited about.

Bethany Lockhart Johnson (01:49):

I don’t know, Dan, I think next time I see you I’m gonna bring a list of some concerns or worries I have, and I would love if you just get right to the solution. I’m actually OK with that.

Dan Meyer (02:01):

All right. Good to know. Good to know. I’ll say I am coming off of a day where I was feeling some teacher anxiety today, because I taught really real students. So just to let you know where I’m coming from here. I taught some seventh grade students at Montera Middle, here in Oakland Unified School District. Taught ’em a lesson outta the Desmos curriculum. And it was one of those lessons where some thorny stuff comes up. I’m talking students who are wrong for smart reasons, who are right for the wrong reasons, and their minds are working so hard trying to figure out inequalities. And I’m like trying to just step into that process as an educator with some curriculum and help shape those ideas. But it’s just … I don’t know, you want it to be as easy as like, “let me just show you how it’s done a few times, and now you got it.” But whew, some of these ideas, they take a long time to form up and they’re really easily reshaped by lots of stuff going on. So that’s where I’m at, anxiety-wise, right now. The teacher anxiety stuff.

Bethany Lockhart Johnson (03:04):

I think there’s probably plenty of teachers who do kind of just say, this is how you do it. And so, from what I have seen of your teaching and what I know of the Desmos curriculum, it is such an opportunity to think hard about the things that we are assuming about our students, assuming about what we know about the math itself. And yeah, that requires some thought.

Dan Meyer (03:30):

Yeah, for sure. I came in ready, like, “When you multiply both sides of an inequality by a negative, this sign flips around.” And I could just say that to kids and say, “Hey, remember that! Write that down!” And a lot of them would do it really well, you know, provided the assessment problems looked like ones we’ve gone over in class. And they’re also learning — in addition to that math, they’re learning that math is a giant sack of tricks they gotta memorize, right? So there’s just these pros and cons. And at the end of the one period I’m gonna teach this week, I was like, “Well, your teacher’s gonna go over that tomorrow, when they’re with you instead of me.” So it felt a bit like I copped out on that one. And I’m just in in my feelings about that right now. And I’m gonna try to come on down here and be present in the math-anxiety world.

Bethany Lockhart Johnson (04:25):

I appreciate you sharing that, Dan. And I think … I have a feeling that you could write a pretty catchy rhyme to allow the students to flip and <starting to rap> “multiply by negative. and dit-dit-dit-dit.” Can you feel it? You picking up that beat?

Dan Meyer (04:40):

Ooh, yeah. A nice little beat. Uh-huh. Yup.

Bethany Lockhart Johnson (04:41):

Yeah. You know, you could come up with something pretty clever, and yet you did not lean on your wordsmithing skills. You said, “No, let us dive in.” So what are you gonna do with this lesson, by the way? What happens now? You popped in for one period, and then what happens?

Dan Meyer (05:03):

Yeah. So this is gonna be a blast. I hope you folks tune in. We’re gonna actually release the footage of me teaching this lesson live. You know, it’ll be replayed live. And on top of that, a couple of my favorite teacher coaches and just smart people about teaching are going to be giving commentary. They are gonna be giving the director’s commentary, the sports announcers’ commentary on what they’re seeing. I beg for their generosity in their commentary. But I think it’ll be a lot of fun. I’ve never seen anything like this before, a commentary track on top of a teaching lesson, in this way. So I’m just gonna gonna be excited to see what they noticed that I didn’t, what they might have done, the thoughts they might have. Maybe I’ll do a post-game interview, you know.

Bethany Lockhart Johnson (05:50):

Ooh, yes!

Dan Meyer (05:50):

With my towel around my neck, <laugh> looking all sweaty.

Bethany Lockhart Johnson (05:54):

Ready, set, grow!

Dan Meyer (05:55):

Like, “Yup, we gave it all out there, you know, just a real team effort.” You know, that kind of thing. We’ll see how that goes.

Bethany Lockhart Johnson (06:02):

I actually love that idea. I love that it’s not just this one random lesson that just kind of floats out there, and it’s about, you walk away with whatever feelings you have, and the students obviously walk away, but that this is gonna help other educators.

Dan Meyer (06:17):

Yeah. Yeah. We’ll multiply my anxiety and make it more people’s anxiety. We’ll see how that goes. So stay tuned on the Math Teacher Lounge feed for that. All right?

Bethany Lockhart Johnson (06:25):

All right! And speaking of anxiety, Dan Meyer, we gotta get to today’s show. You know, last time we had some amazing strategies for helping students from Dr. Truglio from Sesame Workshop. I gotta tell you, I sent that episode to so many of my friends, like, “Listen to these ideas!” and have had some interesting follow-up conversations. And we would love to hear what you think about this season so far, at MTLShow on Twitter or in our Facebook group, Math Teacher Lounge. So today, we’re gonna focus on strategies for supporting teachers.

Dan Meyer (07:00):

Yes. Which is why we’re so excited to bring to you folks Heidi Sabnani, who — we’ve had researchers. We’ve had Sesame Workshoppers. And Heidi Sabnani has been a classroom teacher; she’s teacher-consultant; newly minted doctoral degree holder. We’re so pumped to bring to you folks: Heidi Sabnani.

Bethany Lockhart Johnson (07:25):

Dr. Sabnani, thank you for being here. Can we call you Dr. Heidi? What would you. …

Dr. Heidi Sabnani (07:31):

You can just call me Heidi. Yeah. Heidi is good.

Dan Meyer (07:36):

Right on.

Bethany Lockhart Johnson (07:36):

  1. Heidi, thank you for joining us in the Lounge. We’re so excited to talk with you.

Dr. Heidi Sabnani (07:41):

I am super-honored to be here. It’s really exciting and I just really appreciate the opportunity.

Bethany Lockhart Johnson (07:47):

I will say I don’t have a PhD, although the two people I’m talking with right now, both do, and you’re both like holding up your degrees as we speak and saying, “Wah-wah.” But I imagine that if I did, I’d wanna throw that doctor in more frequently, so.

Dr. Heidi Sabnani (08:02):

Well—

Bethany Lockhart Johnson (08:03):

If I sneak in a “Doctor,” Heidi, it’s only out of respect.

Dr. Heidi Sabnani (08:05):

  1. I appreciate it.

Bethany Lockhart Johnson (08:07):

Dan makes me call him Dr. Meyer all the time.

Dan Meyer (08:10):

You don’t call me Dr. Dan or Dr. Meyer, ever. So—

Bethany Lockhart Johnson (08:13):

I will now!

Dan Meyer (08:14):

—this respect only goes towards Dr. Heidi, it seems. But yeah, we’ll take that off the air.

Bethany Lockhart Johnson (08:19):

Well, we are going to delve into your research on math anxiety soon, because I actually — speaking of becoming a doctor, a new doctor, I have some questions. We have questions about your research, but on a personal level, I really appreciated the way that you share that you yourself experienced math anxiety as a student. So I’m wondering if you could tell us a bit about your own math anxiety, your <laugh> journey through math.

Dr. Heidi Sabnani (08:50):

Yeah, so much like the people in the research that I did, and with the research that I read by others, many of us can tie the beginnings — or like the evil villain origin story of math anxiety — to a particular event, or series of events. And my series of events started, the big blow-up, I guess, in fourth grade. And I had had some struggles in school — I have mild dyslexia and dyscalculia. And so I had always been in the special group of kids who got some extra attention <laugh> from the teacher, or from an aide, or whoever happened to be in the room. But in fourth grade — at that time, they taught multiplication and division facts in fourth grade. Many, many moons ago. And I struggled greatly with just understanding what was happening and why we were moving so quickly. And, my teacher was probably not the best person to be entrusted with my learning at the time. Like, her style may have been OK for others, but it was obvious that she felt like kind of wasting her time with some people in the classroom. And I happened to be one of those people.

Bethany Lockhart Johnson (10:26):

Mmm. You said that really diplomatically, though. <Laugh>

Dr. Heidi Sabnani (10:30):

Well, you know, you look back at things from the perspective of many years. And having made lots of mistakes myself in the classroom as a teacher, I try to give some grace to things that happened, and how you remember them. Yeah, that’s my story, but maybe she had a different one, right?

Bethany Lockhart Johnson (10:55):

Yeah. But fourth grade Heidi was still, you know, still experiencing that. Yeah.

Dr. Heidi Sabnani (11:01):

Yeah. Fourth-grade Heidi didn’t like being in the “dumb group” and didn’t like being told that she would probably not graduate from high school. So that was kind of the general environment. And I got further and further behind in math. The dyslexia was less and less of an issue the older I got, because I had great comprehension. And so I could figure out the fluency thing just by the pattern of language, because mine is mild in comparison to so many who struggle with that. But math was not working in that same way. And I got more and more behind and to the point where I was having to stay in every day at recess. And I had had it after like a month. Like, I’m not staying in at recess anymore to do this math that I don’t understand, by myself. Like, not doing it. So I—

Bethany Lockhart Johnson (11:53):

Which, by the way, if there’s one way to make you hate it, <laugh> like, to engender, to endear you to a subject, could it be, “Let’s have you stay in at recess”?

Dr. Heidi Sabnani (12:07):

Right. And so one day I just stormed out of the classroom, I was like, “I’m not coming. I’m not staying, I’m not doing this anymore. I’m done.” And I can remember her standing up at the top of the hill screaming at me to come back, and I was like, “No way. Not doing it. Done with this.” I went to a parochial school, though, and my dad is a pastor. So that whole little incident blew up in the greater community in a way that I didn’t really anticipate as a fourth grader. And my parents had no idea that this was going on. And so they were shocked and dismayed that their — up until that point — oldest child, rule-follower, had done this. But then even more upset when they found out what was happening with my math understanding, or lack thereof. And they did what they knew best at the time. So my mom was a great memorizer. She has a brain like an elephant. And my dad grew up in the British system in India and Singapore, and it was at that time very much based on memorization. And so they were like, “We are gonna just work really hard. We’re gonna buckle down and do this thing <laugh>.” And so that’s what we did, and that’s where all of it began. It was not — it was just about “We’re gonna learn the facts. We’re not gonna ask questions; we’re not gonna think about it, because it’s just the rules. And if you can figure out the rules or the system or what the teacher wants, and mimic what the teacher is doing, then you’ll be successful.” And it was really successful for me, once I figured that out all the way through. My whole goal in high school when I took high school math was to take enough math courses with a high-enough GPA that when I got my BA in college, that I would never have to take math again. And I succeeded in that and got an English degree and a Master’s in world lit. And I was in no way doing math ever again.

Bethany Lockhart Johnson (14:31):

But little did you know that Future You was going to be researching math anxiety. How did you wind up researching it then? How did you wind up researching math anxiety?

Dr. Heidi Sabnani (14:43):

So I took a job in school improvement when I was working in Ohio, after a number of years teaching high school English in Southern California and Guatemala and Michigan, all over the place. And I took a job in school improvement with a co-consultant who was gonna be doing the math end, and I was gonna be doing the literacy end, and we were just gonna go in, and I was gonna make kids love reading, and she was gonna make kids love math, and it was gonna be so fun. And then she decided she didn’t like working with adults and they couldn’t find anyone else. And my boss said, “So you’re just gonna do both for the rest of the year.” After that year, I got requested to go back and, and do this again. I said, “Well, if I’m gonna do this, I’m going to go back and reteach myself the math in ways that I wish that fourth-grade Heidi had learned it, and fourth-grade-and-up Heidi had learned it.” And so that was like the, the beginning of the switch. And so now equal amounts of time in my career have been spent in both. But when I started, when I continued working, when I left the classroom to continue working with teachers, and when I transitioned more into an elementary setting, I began to notice the same behaviors that I had in high school of avoiding math, and avoiding teaching math, were happening in the classrooms that I was supporting. And so I would have teachers come and say, “Oh, can we talk about this literacy thing?” And even if it was like a math meeting, or we were supposed to split the time evenly, and ohhh, for some reason the literacy time talk would just like move over <laugh>. And then there was no time to talk about math at the end. And “Oh, that’s just too bad.” Like, we’re just gonna move on to this next thing. Funny how that happens, right?

Bethany Lockhart Johnson (16:32):

Yeah. <laugh>.

Dr. Heidi Sabnani (16:34):

And noticing teachers’ behaviors around going to and or avoiding math professional development that I was giving. Or getting sick. Or like having to leave the room for a long period of time. And so I began to notice these behaviors. And initially I thought I wanted to look at math anxiety in children, which is one branch of the research that I started with. But as I got into things more, the people that I have the most influence in are adults right now.

Dan Meyer (17:09):

Right.

Dr. Heidi Sabnani (17:09):

And so as I started looking at the research that had already been done, I feel like we do a really nice job of admiring the problem of math anxiety, and we do less in the “what to do about” phase. And so I was like, “Well, if I’m going to continue to be in this career and in this profession, then I need to be doing something in the space of ‘what are we gonna do about it?’” And so that’s how I switched to looking at “what do we do to help teachers?” Particularly elementary school teachers, because that’s the area of greatest need, based on previous research that we could at least do something to help.

Dan Meyer (17:51):

Yeah. A previous guest mentioned that a lot of research is better understood as me-search, especially in this kind of arena, where we’re going back in to try to understand what it was that happened for us and how to prevent it for future generations. And I have nothing but respect for that motivation right there. And your point is well-put, that it is very possible to spend a ton of time examining math anxiety from every angle, every facet, you know, put it up there on a mounted board and admire it … and there’s a lot of value there, but I appreciate that you’re moving into, “So, now what?”

Dr. Heidi Sabnani (18:27):

Yep.

Dan Meyer (18:28):

And so I’d love if you’d share with us and our listeners the broad details of your study, and what you ultimately found. Like, if there are any large takeaways here, what were they?

Dr. Heidi Sabnani (18:40):

Yeah. So a couple of things to kind of just lay a little bit of the groundwork. One out of four teachers say that they have math anxiety. Those numbers increase rapidly, the younger of the grades that the teachers teach. So if we think about preK to two, it’s about 88%, based on other people’s research. So I was like, “Well that’s a lot of people <laugh>!” And so, that’s the scope of the problem. And so I was thinking, “OK, what do we do in these moments?” Because other researchers had said they’re spending — when they don’t like it, they’re spending less time teaching math and avoiding it, or relying on methods that were done to us. Just out of fear of trying something different, at many times. And so one thing that has become more prominent in math education since I transitioned 16 years ago into this has been the role of coaches in school systems. And so one of the questions I wanted to think about was, “What can coaches or math specialists who work with adults as well do to help the teachers that they work with?” So that was kind of the lens that I was looking at. Like, let’s think about the systems that we currently have in place. Is there something that we could be doing that would help teachers, that wouldn’t be so huge or so monumental that with little shifts in our own behavior as coaches or professional development providers that we could make that would make a difference? So that being said, this was a qualitative study, so a small group of people in very intense settings. So I kind of always wanna preface that, because in academic world, you know, there’s <laugh> all sorts of thoughts about that. So I had asked teachers from districts that I work with who self-identified as having math anxiety if they would be interested in the study. So, this is what we’re thinking of, this is what it would look like, and the scope of the support they would have.

Bethany Lockhart Johnson (20:50):

So basically you’re tracking these four teachers who self-identified as math anxious. And were you serving as their coach and kind of seeing what was working?

Dr. Heidi Sabnani (21:00):

I was serving as their coach. Yeah. I was serving as their coach during that time period. And some fairly recent research that had been done was in the idea of “Can we do some reflective conversations or reflective writing around where your math anxiety started, and how that makes you feel both as a teacher of mathematics now, because you are teaching math, and how that affects your identity as a mathematician?” And so that was the first starting point. And that was a really critical moment that I’m glad that I had stumbled across the research on, because it turned out that having someone hear and acknowledge that what happened to them was both wrong and inappropriate, in many cases, and in a couple instances, was traumatic and also abusive — that that mattered. That it was OK to feel anger and hurt and frustration based on what happened to you in the past. And then have that moment to reflect on, “OK, so what do you want the classroom environment that you’re building as a teacher to feel like for your students?” So it was turning that moment of how they felt to thinking about, then, what kind of environment do we wanna make within the math classroom? And what steps can we take to ensure that happens? So that was like, Step One is just thinking about what that looks like. What kind of math identities then do you want to create for your students? Because all of the teachers were very concerned with not continuing the cyclical nature that often happens with math anxiety, from teacher to student and back again.

Bethany Lockhart Johnson (22:54):

Well, and even that validation, right? Like, how many of them hadn’t even had, like you said, had that? We had another, when in our first episode, Dr. Gerardo Ramirez talked about that validation and how key.

Dr. Heidi Sabnani (23:09):

Yeah. That was the first thing. The next step of it, which very different from what I often do — I don’t generally go in and model for teachers — just me, taking over your classroom. I really like to co-plan with teachers and co-teach with teachers and have it not feel like they’re losing control over what’s happening in that moment. And that’s generally the way that I go in when I’m doing professional development in a classroom, right? Like, I’m working with the teacher and we’re a team; we’re doing this together. But in these four cases, these teachers were very, very resistant <laughs> to co-teaching. And so I said, “OK, well, let’s throw everything out. Let’s try whatever it happens to be.” So the modeling aspect turned out to be really important, in part when three out of the four cases, because they were like, “Oh, I can do that.” <laugh> like, Well, yeah, I know you can! Like, it was that having a moment to sit back and see someone else doing it — which is harder to do when you’re co-teaching, right? It’s harder to be reflective in the moment when you’re still thinking about the teaching choices you’re making, because you’re both co-teaching.

Bethany Lockhart Johnson (24:24):

Right. Or sometimes you see, like in co-teaching, it falls into “one teach, one manage,” you know, or something like that.

Dr. Heidi Sabnani (24:31):

Yes.

Bethany Lockhart Johnson (24:31):

I have definitely fallen into that. But you, by modeling … it was almost, I don’t know, it feels like you’re kind of holding their hand. Like, “I’ll show you!” And not that it has to exactly look like that, right? But you found if a coach is coming in and the teacher gets to sit back and basically watch their students learn, they’re probably gettinga ton of information about their students, and they’re really learning some teaching strategies for mathematics that they can then like dip their toe in. I think? <Laugh> Am I kind of thinking of this? I’m trying to picture this and it feels rich and rife with possibilities <laugh>.

Dr. Heidi Sabnani (25:16):

Well, and it, it turned it from … I think sometimes, when I go into a classroom, I learn so much from watching teachers and being able to sit and listen to students, that you don’t always have the luxury of when you’re the teacher. <Laugh> Right? It’s so much harder to be like, “OK, I’m gonna be watching what a kid does, because I’m hoping someone uses this strategy, so I can connect it to this other person’s strategy, so that we can take that apart and look at it and really have immediate discussion around it.” Those are all so many things that are happening in the moment as a teacher. You don’t get to sit back and look at it from a researcher kind of lens. Or look, you know, from the up-above lens. And when I had these conversations with teachers, I was like, “That’s what I want you to do. I want you to be able to sit back and look at all the things that are happening.” Because then you begin to notice not only the moves that the teacher — in this case, me — who was modeling for them was doing, but also the student conversations. And it was almost like having a case study within that moment, where they got to sit back and just experience, versus thinking about all the decisions that they would make at the moment. So that was something that was really surprising to me.

Dan Meyer (26:33):

Yeah. And I love the idea that they’re seeing the pedagogical moves, but they’re also experiencing perhaps a sense of math that’s de-stressed. You know, they are allowing themselves to sit next to students and feel as though they are a student, in ways that if you’re co-teaching, you are still like enmeshed in the gears of the whole lesson. I wonder if that’s a part of this too. So I’m hearing from you that we’re taking these teachers who have all admitted to some math anxiety, and that one of the interventions, or one of the findings, was that modeling worked really well for, again, this set of teachers. But you modeling lessons that highlighted mathematics, that was less anxious, that helped the teachers see that students were engaging in really productive un-anxious ways, brave ways. Were there other kinds of takeaways that you experienced there?

Dr. Heidi Sabnani (27:24):

Yeah. So in addition to that, we had to think about and start at Step One. 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 seen it taught. And so in her situation, she had had one course in her teacher preparation program, that was on fractions.

Bethany Lockhart Johnson (27:54):

That’s often the case, right? One math methods course! Help, we have to get it all in in this semester! <Laugh>

Dr. Heidi Sabnani (28:01):

<Laugh> Yes. And so she came in and said, “I feel like I have to start at the beginning.” And so there was no question that was inappropriate, or that we weren’t going to explore or think about. And so that was, I think, the starting place with that particular teacher. And then one other, who was kind of in her same age range, where we had to start thinking about, “OK, how did you learn as a learner? What ways are you seeing your students learn as learners? And then let’s focus on those first as the areas that you wanna explore in your teaching.” And so a lot of that ended up being much more visual and hands-on ways of exploring. And so those were some of the changes in, I think, pedagogy that were the most significant. In a couple of cases, these are early elementary teachers who had had one experience with manipulatives in their whole teaching career up until that point. And so one teacher brought me a bucket of Cuisenaire rods and said, “These are in my room. I don’t know what they are. <Laugh> Are we building things with them? Are they blocks that are just small? <Laugh> Like what are they for?”

Bethany Lockhart Johnson (29:20):

Yes!

Dr. Heidi Sabnani (29:21):

And so, <laugh> it was that idea of, “OK, let’s, let’s explore all the different ways that we can use these, and that we can think about how your students might learn best with this particular tool that you have in your room.”

Bethany Lockhart Johnson (29:34):

So hearing you talk about this research — which by the way, I know, you’re like, for our listeners, it’s all, “Quick, boil down your years and hours of research and synthesize it for us.”

Dan Meyer (29:50):

Your life’s work.

Bethany Lockhart Johnson (29:50):

In a little tiny neat package. But really though, even though I know there’s so many layers to your research, and your work with these teachers, I wanna flag for our listeners that even the things that you’ve identified for us, you were giving teachers space — as coach, giving teachers space, and validating their experience as a mathematician, as you know, as a young student, right? Making space for that experience and validating “Yeah, that was really lousy and your math anxiety is real.” Like, Step One is already powerful. And then you’re creating space where they get to be in their classroom as a learner, right? And have a lesson modeled. And then you’re creating more <laugh> space for them to learn and ask questions. And I have absolutely seen teachers like, “I don’t know what to do with these,” and kind of shove aside the district-provided tools or the curriculum-provided tools. And so even those things, Heidi — Dr. Heidi <laugh> — you know, even if … I don’t know, for me, I am listening to you and just holding those points in mind and feeling like that, alone, if a coach did even just that … I know there’s so much more to it, but what a powerful opportunity for reclaiming math as an educator, right? That’s what I’m feeling.

Dr. Heidi Sabnani (31:25):

Well, and I was hoping that there wouldn’t be … I mean, OK, it’s a double-sided hope. If there was something like so novel and so fantastic that was so different from the things that we have already at our disposal, that would’ve made a much better book or dissertation. <Laugh> But the reality is, there are things that we already know work. And we don’t often take the time or, or are given the time to be able to explore those things. Right? So even as coaches, you have district initiatives or things like, “this is what we’re working on this year,” and that’s fantastic, right? We keep those things moving forward. But if we’re thinking about coaching teachers with math anxiety, no teacher with math anxiety is going to be coming to NCTM.

Dan Meyer (32:16):

Right. Right. Or the training.

Dr. Heidi Sabnani (32:19):

Or the training. They’re like, “Oh, PD day? Literacy! Yes, please! Bye!” You know, it’s that piece of it. So when we have these moments, the coaching is the opportunity to provide that just-in-time kind of professional development for teachers, if we go at it in a slightly different way. It does not have to be huge. It can be things like, they feel that they’re stronger in literacy. Well, then, let’s explore some of the ideas around math, anxiety and math identity and examples of people who’ve overcome either those things or other barriers in their life. And how can those things help form not only your students’ math identity, but your math identity. And it gives entry points in ways that you have access to if you’re a person’s coach.

Dan Meyer (33:18):

So in that sense, I’d love to know from you, if someone came to you at a coach’s meeting at NCSM and asked you, “What is something I can do right now to support the teachers at my site and my district, who are commonly experiencing math anxiety?” What is something that you would offer them in that brief moment you had with that coach?

Dr. Heidi Sabnani (33:40):

So it is hearing their story first. That’s the big one. And then, can you, in your coaching, provide opportunities to slow down? We all have these pacing guides in some form or another, that drive the things that are coming. Is there a way that you can set up meetings a month or more in advance of the content that those teachers are going to teach? Can we explore a month in advance, that content? And ways to teach it and understand it? There’s the ways to teach it, but there’s also like, “What is this math and how do kids experience this math?” What kind of experiences do we want to have ourselves as learners and then have as kids? If we can create cycles like that, that then don’t feel so rushed. It’s so hard when we’re like, “Oh, we have a planning meeting and we’re meeting with our coach!” And you’re teaching this lesson tomorrow. “Learn all this stuff about adding and subtracting on a number line. Go!” It’s so fast. And so if we had those opportunities to build in cycles, where we could slow down that process, it would make a huge difference in the lives of so many teachers. And it’s finding that time and the willingness. If you listen to teachers, they will work with you. If you validate what happens to them, and acknowledge that sometimes that still happens to us. I mean, I still have experiences like that. Sometimes I’ll walk into a classroom and I’m like, “Oh, I forgot how to do that!” You know, like, “I’ve not reached that far in my remaking of my own education!”

Bethany Lockhart Johnson (35:24):

Yehhhh, heh heh heh.

Dr. Heidi Sabnani (35:25):

<laugh>. And you think, “I don’t wanna look like an idiot. I’m the math consultant who’s here to duh duh duh.” All of those things still come up. Yeah. And stopping and saying like, “OK, everybody, this is what’s happening to me right now.” <laugh> The vulnerability you have, you have to think about that. Even if you don’t have experiences of math anxiety in your own life. Let’s say you always rocked out in math, and you’re now a math specialist and you love it. You think it’s the most spectacular thing. There’s some other element in your life where you face some anxiety. All of us do. So it’s about thinking about, “OK, this is where I experience anxiety. Can I find that in the teachers that I work with? And then, can my teachers find that in the students they work with?” You know, the teachers, as they begin to reflect on their own experiences, began noticing which students always went to the nurse during math time, always asked to go to the bathroom during math time, always couldn’t find a pencil, or whatever it happened to be. And they began to be more aware of their students’ behaviors as well, and could then say, “Hey, let’s sit and talk about how you feel in math class. Like, I’ve been noticing that when it’s time for math, like your stomach hurts. Can we talk about like why that might be?” Because those teachers with math are more attuned, often, to those students. And so it just … the time factor, I guess is, is the bottom line.

Bethany Lockhart Johnson (36:59):

I just wanna say, it’s so great to have you in the Lounge. Because I think you’re really bringing this perspective that we haven’t talked about, which … we are not expecting coaches to walk in and know it all. That’s actually the exact opposite. You are allowed to be vulnerable. We are not saying, “Come,” quote-unquote, “Fix this.” It’s like, “Hey, how can you facilitate and make space?” And I feel like you have given us just a taste of like how that might be possible. And you know, I think even if it’s just a chance for teachers to reflect on their own experience in math, even that would probably be kind of revolutionary for — and I don’t say that word lightly — for some PD spaces, especially if they have another peer in their team that is like quote-unquote, “a whiz,” or like, “Oh, I don’t feel like I can be vulnerable in my math anxiety because this teacher seems to know it all.” But you’re creating space where it’s like, “Hey, we all have strengths. We all have areas where we could support each other.” And I love that invitation for coaches. I love that invitation for teachers. And … yeah. I’m just, I’m so glad we get a snapshot of your research. Again, I know, I respect that this is not the whole thing!

Dan Meyer (38:22):

Can we find … is there a link to your dissertation in the show notes, for those of us who peruse dissertations? Can we add something here? Think about —

Dr. Heidi Sabnani (38:29):

Oh, I have no idea!

Dan Meyer (38:30):

Just think about it. Just think about it. But —

Dr. Heidi Sabnani (38:34):

It’s somewhere on ProQuest. It did get some. …

Dan Meyer (38:36):

Right on.

Bethany Lockhart Johnson (38:36):

Is that a thing, Dan? Could I go, like, Google your dissertation?

Dan Meyer (38:39):

You definitely could. Yeah, for sure. It’s around. Yeah, same way. Well, that’s awesome. And I think it’s so helpful for those who write those enormous unwieldy essays to, you know, distill it in different ways. I hope it’s been … we’ve enjoyed so much, hearing you carve up a huge project into pieces that were really helpful for us to think about here in the Lounge. Thank you so much for coming on and hanging out with us. Dr. Sabnani, it’s been a pleasure.

Dr. Heidi Sabnani (39:06):

Hey, I’m happy to do it any time. Always the biggest joy in the work that I do is little changes in a positive direction.

Dan Meyer (39:18):

Right on.

Dr. Heidi Sabnani (39:19):

That’s all that this is about. Right? Whether it’s kids, whether it’s teachers, whether it’s administration. The work that we all do is so valuable, and it is more and more difficult over time. And just giving ourselves a little bit of space to think about and acknowledge that, I think, is really important. So I appreciate you all making space as well. And thinking about this idea. Because <laugh> we’re math people! And we don’t have math anxiety! Right?

Bethany Lockhart Johnson (39:51):

<laugh>

Dan Meyer (39:51):

So people would assume

Dr. Heidi Sabnani (39:54):

<laugh>. Yeah.

Bethany Lockhart Johnson (39:54):

Thank you so much. You’re welcome back in the Lounge anytime. <laugh> Thanks so much for listening to our conversation with Dr. Heidi Sabnani, consultant and co-host of the show “Math for All.” I can’t get enough about talking about math anxiety!

Dan Meyer (40:13):

Especially from people who are working with teachers so closely.

Bethany Lockhart Johnson (40:18):

Yes, totally. I loved that lens of, “Hey, look at what happens if we actually focus on the teacher’s experience and help them kind of reclaim this comfort, this sense of identity, relationship with math that’s positive. How does that impact their teaching?” I loved talking about it, and I’m really interested in how that work continues to evolve. So thank you so much Dr. Sabnani, for your time. And you know, listeners, please keep in touch with us on our Facebook, in our discussion group, Math Teacher Lounge Community, or you can find us on Twitter at MTL show.

Dan Meyer (40:58):

If you haven’t already, please subscribe to Math Teacher Lounge, wherever you get podcasts. Also, if you like what you’re hearing, please rate us and leave us a review. It will help more listeners find the show. And it just makes me and Bethany feel good about ourselves, too. You can find more information on all of Amplify’s shows at our new podcast hub. Go to Amplify.com/hub.

Bethany Lockhart Johnson (41:20):

You know, Dan, I also always like to say, I find most of my podcasts through recommendations from other listeners, friends, folks. So if you like what you’re hearing, share it in your teacher lounge. Just, like, on break, turn it up and start vibing and having the conversation right there.

Dan Meyer (41:40):

Yep. Yep. I got a better idea. Take the link to this podcast and then copy it and find the longest — the thread in your inbox with the most people on it. One of those ones that’s like, someone accidentally cc’d like 500 people, everyone at your school. Press “reply.” This is crucial. Not “reply,” but “reply all.” Paste that link in. Press “send.” Watch what happens.

Bethany Lockhart Johnson (42:04):

Nothing but good —

Dan Meyer (42:04):

Good fortune will be yours.

Bethany Lockhart Johnson (42:06):

Nothing but good things can happen when you send this to 500 people in the next 10 minutes. Next time on Math Teacher Lounge, we’re gonna be joined by Dr. Marjorie Schaeffer of St. Mary’s College for a conversation about math anxiety, and specifically Dan, how parents and caregivers, how their disposition influences the way their kiddos feel about math.

Dr. Marjorie Schaeffer (42:29):

I think the most important thing we know from literature right now is that high-math-anxious parents, when they interact with their children, their children learn less math over the course of the school year.

Bethany Lockhart Johnson (42:40):

And get this, she’s gonna talk to us about an app that just might be something worth, you know, heading over to the app store for.

Dan Meyer (42:49):

I’ve used some apps, I have opinions, and I can’t wait. We just share recommendations on apps with Dr. Schaeffer.

Bethany Lockhart Johnson (42:56):

That’s next time on Math Teacher Lounge. Thanks so much for listening.

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What Dr. Heidi Sabnani says about math

“Much like the people in my research, many of us can tie the beginnings or the ‘evil villain origin story’ of our own math anxiety to an event or series of events.”

– Dr. Heidi Sabnani

Consultant and Co-host of Math 4 All

Meet the guest

Heidi Sabnani is always surprised that she works in math education. She developed math anxiety as a young student and spent much of her school life and early career avoiding math. After teaching English in the United States and Guatemala, and earning her MA in World Literature, she found herself in the uncomfortable position of working in math classrooms as a school improvement consultant. Once she realized that her life was going to involve math, Heidi decided to relearn math in the ways she wished she had learned the first time around. 18 years later she is still learning with and from the students and teachers she has the privilege to serve.

Heidi’s doctoral research at Northeastern University focused on interventions for math anxiety in elementary teachers. She currently works as a consultant, speaker, and author.

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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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Winter Wrap-Up 03: Ideas to build math fluency

Promotional graphic for "Math Teacher Lounge" episode featuring Valerie Henry, Ed.D., on ideas to build math fluency, with a photo of Valerie Henry in the bottom right corner.

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.

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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.

Stay connected!

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We’ll also share new and exciting free resources for your classroom every month.

What Valerie Henry says about math

“A lot of very fluent adults don’t always have every fact memorized. ”

– Val Henry

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.

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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:

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Mathigon: the mathematical playgrou…

Math games and manipulatives for online and remote learning.

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Amplify Classroom Grades 3–12

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We are the program for middle school.

Amplify ELA is a blended curriculum designed specifically for grades 6–8. With Amplify ELA, students learn to tackle any complex text and make observations, grapple with interesting ideas, and find relevance for themselves.

Students are engaged through dynamic texts, lively classroom discussions, and meaningful digital experiences. Request a free sample of Amplify ELA to see for yourself.

Built for middle school teachers and students

Built specifically for middle school, Amplify ELA is an interactive core curriculum that brings complex texts to life. Amplify ELA inspires students to read more deeply, write more vividly, and think more critically.

All-green rating on EdReports

The results are in! Amplify ELA received a near-perfect score by the independent review group.

Our approach

We are the program for middle school teachers, offering rich texts that are a delight to teach, better connections with your students through powerful differentiation and assessment tools, and step-by-step instructional guides that save you time and simplify your day.

We empower students to become critical thinkers.

With text always at the center, students are encouraged to make meaning for themselves. They develop ideas and opinions on real-world, relevant texts, instead of focusing on right or wrong answers.

We provide opportunities for all students to work “up.”

Multiple entry points and differentiated supports allow every student, regardless of fluency or ability level, to engage deeply with the same complex texts and rigorous curriculum.

We assess while you instruct.

Formative assessment reports provide a continually updated picture of how each student is progressing with key skills and standards. Each learning moment provides a small piece of data, allowing you to keep teaching while building a clear understanding of student performance.

Download a free white paper

Beyond “make it fun”: Four principles of true engagement in middle school ELA

Download the white paper

What’s included

Rigorous core curriculum that empowers teachers and engages middle school students

Student edition

Available digitally and in print, the student materials guide middle schoolers through complex texts and writing by:

  • engaging students with high-quality narrative and informational texts
  • providing videos, audio supports, and digital experiences that capture their attention
  • keeping all of their writing in one place with the personal writing journal

Teacher edition

Available digitally and in print, the Teacher’s Edition contains all of the information teachers need to facilitate classroom instruction, including:

  • detailed lesson plans
  • video teacher tips embedded in the lesson
  • standards alignment and exit tickets
  • real-time differentiation strategies
  • robust reporting

Interactive Quests

Quests are fun, week-long explorations where students practice analytical reading, writing, speaking, and listening skills all while building a strong classroom community.

Digital library for independent reading

Amplify Library: Our expansive digital library includes more than 650 fiction and nonfiction, classic, and contemporary titles.

Amplify ELA makes teachers’ lives easier

We help teachers make sure the standards are covered, the skills are taught, your students are scaffolded and encouraged, and the test is prepped.

  • Embedded differentiation to support all readers
  • Informative and streamlined assessment system
  • Robust reporting that tracks progress
  • Powerful feedback tools

Inspiring the next generation of Rochester scientists, engineers, and curious scholars

Dear Rochester educator,

We’re extremely excited to be part of your science review process.

Built from the ground up for three-dimensional, phenomena-based learning, Amplify Science helps your Rochester scholars go from learning about to figuring out scientific concepts.

Explore the sections below and learn how Amplify creates rigorous, relevant learning experiences for the next generation of scientists, engineers, and curious citizens.

—Jennifer Fosegan, Rochester Senior Account Executive

Standards-based and grounded in research

Amplify Science is an engaging new core curriculum designed for three-dimensional, phenomena-based learning. Developed by the science education experts at UC Berkeley’s Lawrence Hall of Science and the digital learning team at Amplify, our program is used by hundreds of schools across the country, including New York City Public Schools, Chicago Public Schools, and Denver Public Schools.

Amplify Science was designed from the ground up to meet the Next Generation Science Standards. To ensure alignment to the New York State Science Learning Standards (NYSSLS), our partners at the New York City Department of Education created additional resources that can be made available for RCSD to implement.

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:

Phenomena-based approach

In each Amplify Science unit, students take on the roles of scientists or engineers in order to investigate a real-world problem. Students work to define the problem and collect and make sense of evidence. Once the context is clear, students collect evidence from multiple sources and through a variety of modalities.

At the end of the unit, students are presented with a brand-new problem, giving them an opportunity to apply what they’ve learned over the course of the unit to a new context. This represents a shift from asking students to learn about science to supporting students in figuring out the science.

Resources to support your review

What’s included

COMPONENT

FORMAT

Teacher’s Guides and digital experience

Available digitally and in print, the Teacher’s Guides contain all of the information teachers need to facilitate classroom instruction, including detailed lesson plans, classroom slides, high-level overview documentation, differentiation strategies, standards alignments, materials and preparation steps, teacher support strategies, and in-context professional development, possible student responses, and more.

Print and digital

Hands-on materials kits

Hands-on learning is integrated into every unit of Amplify Science. Each hands-on activity is supported through clear instructions for the teacher, as well as easily accessible materials in unit-specific kits. Each kit contains hands-on materials, both consumable and nonconsumable, and various print materials (e.g., Vocabulary and Key Concept cards). With Amplify Science, students can actively participate in science: gathering evidence, thinking critically, making observations, and communicating their claims

Kit

COMPONENT

FORMAT

Student Investigation Notebooks

Available for every unit, the Student Investigation Notebooks contain instructions for activities and space for students to record data, reflect on ideas from texts and investigations, and construct explanations and arguments.

Print and digital

Student books

The age-appropriate Student Books in Amplify Science allow students to engage with content-rich text, obtain evidence, develop research and close reading skills, and construct arguments and explanations about the ideas they are learning in class.

Print and digital

Student digital experience

Students can easily engage with the student digital experience, so effective learning can occur in every type of classroom environment.

In grades 4–5, students are introduced to digital simulations. Developed exclusively for Amplify Science, these digital tools serve as venues of exploration and data collection, allowing students to discover and construct their understanding of science concepts and phenomena.

Digital

Spanish parity

Amplify Science is committed to providing support to meet the needs of all learners. For Spanish-speaking students, greater access to rich science content is achieved with Amplify Science through the use of a pedagogical approach that offers multiple points of entry. In addition, Spanish language supports are available across the curriculum, including Spanish kits that offer Spanish versions of all student-facing print materials, as well as Spanish digital licenses for teachers. Learn more about the Spanish components available across Amplify Science.

The same rigor in terms of scientific accuracy, literacy development, and the use of rich content and language in the creation of the Amplify Science Spanish materials. To ensure equity, all Spanish materials were carefully translated using academic Spanish, paying particular attention to consistency and the use of grade-level-appropriate language in order to support language development.

Review online

Ready to explore on your own? Follow the instructions below to access your demo account.

First, watch this navigation video. Then, click the orange button “Log in to Amplify Science” to log in.

  • Select Log in with Amplify.
  • Enter username and password:
    • Teacher username: t1.rcsdtrial@demo.tryamplify.net
    • Student username: s1.rcsdtrial@demo.tryamplify.net
    • Password (both teacher and student): Amplify1-rcsdtrial

Disciplinary Core Ideas (DCI) review
Each Amplify Science unit is designed around a unit-specific learning progression that aligns with NGSS disciplinary core ideas (DCI) and crosscutting concepts. The levels that comprise the unit’s learning progression are cumulative. As students progress through the unit, they are able to integrate prior understandings with new insights, and there are continuing opportunities for students to master conceptual understanding of early unit content in subsequent chapters of the unit.

This means that standards are often addressed across entire units instead of in one particular activity or lesson. Thus, the lessons noted below are examples of where the concept represented in the listed DCI is addressed, but this list should not be considered exhaustive. Instead, students have frequent opportunities to engage with these ideas throughout the unit, the grade, and the grade band. 

To view the specified lessons, explore our RCSD Digital Review Guide or select a grade level below.

DCI ESS2.D: Weather and Climate
Before you begin reviewing these lessons, make sure to locate the following Student Books from your Unit Kit: What is the Weather Like Today? and Tornado! Predicting Severe Weather

Select the Sunlight and Weather unit, click Chapter 1, and locate the lessons below:

Lesson 1.1

  • Activities 2 and 3, Step-by-step tab
  • Student bookWhat is the Weather Like Today? (note: located in your Unit Kit)

Lesson 1.2

  • Activities 1 and 3, Step-by-step tab

Lesson 1.3

  • Activities 1 and 2, Step-by-step tab

Lesson 1.4

  • Lesson Brief, Digital Resources, “Playground Weather Calendars and Playground Weather Graphs (Completed)”
  • Activity 1, Step-by-step tab (especially steps 5, 9, and 10) and Teacher Support tab (“Assessment, Assessment Opportunity: Assessing Students’ Understanding of Types of Weather”)

Lesson 5.1

  • Activity 1, Step-by-step tab (especially steps 6–7) and Teacher Support, Assessment tab (“Assessment Opportunity: Assessing Students’ Understanding of Weather and Why We Measure It”)
  • Student book, Tornado! Predicting Severe Weather (note: located in your Unit Kit), pages 6–9

DCI PS4.A: Wave Properties
Before you begin reviewing these lessons, make sure to locate the following materials from your Unit Kit: Light and Sound Student Investigation Notebook; Student Book: What Vibrates?

Select the Light and Sound unit, click Chapter 4, and locate the lessons below:

Lesson 4.1

  • Lesson Brief, Digital Resources, “Assessment Guide”
  • Activity 3, Step-by-step tab (especially steps 1–12)
  • Light and Sound Student Investigation Notebook, page 24 (note: located in your Unit Kit)

Lesson 4.2

  • Activity 2, Step-by-step tab and On-the-Fly Assessment (hummingbird icon)
  • Activity 3, Step-by-step tab and On-the-Fly Assessment (hummingbird icon)
  • Activity 4, Instructional Guide
  • Student bookWhat Vibrates? (note: located in your Unit Kit)
  • Light and Sound Student Investigation Notebook, page 25 (note: located in your Unit Kit)

Lesson 4.3

  • Lesson Brief, Digital Resources, “I Hear a Sound. What Vibrates? Mini-Book copymaster”
  • Activity 1, Step-by-step tab (especially steps 5–11, 13), and Teacher Support tab (“Instructional Suggestion, Going Further: Sound Can Cause Vibrations”)
  • Activity 3, Step-by-step tab
  • Activity 4, Step-by-step tab and On-the-Fly Assessment (hummingbird icon)

DCI LS2.A: Interdependent Relationships in Ecosystems
Before you begin reviewing these lessons, make sure to locate the following materials from your Unit Kit: Plant and Animal Relationships Student Investigation Notebook; Student book A Plant is a System.

Select the Plant and Animal Relationships unit, click Chapter 1, and locate the lessons below:

Lesson 1.6

  • Activities 2–4, Step-by-step tab
  • Plant and Animal Relationships Student Investigation Notebook (note: located in your Unit Kit), pages 15–19

Lesson 1.7

  • Activity 2, Step-by-step tab, Possible Responses tab, and Critical Juncture Assessment (hummingbird icon)
  • Activity 3, Step-by-step tab

Lesson 2.2

  • Activity 2, Step-by-step tab (especially steps 4–12) and Possible Responses tab
  • Student bookA Plant is a System (note: located in your Unit Kit)

DCI ESS2.D: Weather and Climates
Before you begin reviewing these lessons, make sure to locate the following materials from your Unit Kit: Weather and Climate Student Investigation Notebook; Student Books Dangerous Weather Ahead and Sky Notebook.

Select the Weather and Climate unit, click Chapter 4, and locate the lessons below:

Lesson 1.4

  • Activity 2, Step-by-step tab 
  • Student bookSky Notebook (note: located in your Unit Kit)

Lesson 2.3

  • Activity 3, Step-by-step tab and Possible Responses tab
  • Weather and Climate Student Investigation Notebook, page 28 (note: located in your Unit Kit)

Lesson 3.2

  • Lesson Brief, Digital Resources, “Anchorage, Queenstown, and Saint Petersburg Graphs copymaster”
  • Activities 2 and 3, Step-by-step tab

Lesson 3.3,

  • Activity 2, Step-by-step tab, Possible Responses tab, and On-the-Fly Assessment (hummingbird icon)

Lesson 3.6

  • Activity 1, Step-by-step tab (especially steps 3–5) and On-the-Fly Assessment (hummingbird icon)

Lesson 3.7

  • Lesson Brief,  Digital Resources, “End-of-Unit Writing: Arguing About Future Island Weather Version A copymaster” and “Assessment Guide”
  • Activity 3, Step-by-step tab (especially steps 3–7)

Lesson 4.2

  • Activity 2, Step-by-step tab, Possible Responses tab, and On-the-Fly Assessment (hummingbird icon)
  • Student book, Dangerous Weather Ahead (note: located in your Unit Kit)

DCI PS4.A: Wave Properties
Before you begin reviewing these lessons, make sure to locate the following materials from your Unit Kit: Student books Warning: Tsunami! and Patterns in Communication.

Select the Waves, Energy, and Information unit, click Chapters 1 and 3, and locate the lessons below:

Chapter 1

Lesson 1.4

  • Activity 1, Step-by-step tab (especially steps 1, and 4)
  • Student bookWarning: Tsunami! (note: located in your Unit Kit)
  • Activity 2, Step-by-step tab, On-the-Fly Assessment (hummingbird icon), and Teacher Support tab (“Instructional Suggestion, Providing More Experience: Waves in Water”)

Chapter 3

Lesson 3.1

  • Activity 2, Step-by-step tab (especially steps 4–8) and On-the-Fly Assessment (hummingbird icon)
  • Activity 3, Step-by-step tab and Waves, Energy, and Information Simulation

Lesson 3.2

  • Activity 3, Step-by-step tab, On-the-Fly Assessment (hummingbird icon), and Waves, Energy, and Information Simulation 

Lesson 3.3

  • Activity 4, Step-by-step tab and On-the-Fly Assessment (hummingbird icon)
  • Student bookPatterns in Communication (note: located in your Unit Kit), pages 6–7

DCI LS2.A: Interdependent Relationships in Ecosystems
Before you begin reviewing these lessons, make sure to take out the following materials from your Unit Kit: Student books Restoration Case Studies and Walk in the Woods; Organism Print Name Cards: Set 1.

Select the Ecosystem Restoration unit, click Chapters 1, 2, and 3, and locate the lessons below:

Lesson 1.6

  • Activity 2, Step-by-step tab, Possible Responses tab, and Ecosystem Modeling Tool (Box 2 on student apps page, “1.6 Healthy Ecosystem Model”)
  • Activity 3, Step-by-step tab (especially steps 2 and 3), Possible Responses tab, and Critical Juncture Assessment (hummingbird icon)

Lesson 1.7

  • Activity 2, Step-by-step tab
  • Activity 3, Step-by-step tab (especially steps 3–7) and On-the-Fly Assessment (hummingbird icon)
  • Printable Resources, Print Materials (8.5” x 11”), Organism Name Cards: Set 1, pages 12–17 (note: located in your Unit Kit)

Lesson 1.8

  • Activity 3, Step-by-step tab (especially steps 6–8) and Possible Responses tab

Lesson 2.3

  • Activity 3, Step-by-step tab (especially steps 1–4), Possible Responses tab, and Ecosystem Modeling Tool (Box 3 on student apps page, “2.3 Plant Needs Model”)

Lesson 2.5

  • Activity 3, Step-by-step tab
  • Student bookRestoration Case Studies (note: located in your Unit Kit)

Lesson 3.2

  • Activity 2, Step-by-step tab
  • Student bookWalk in the Woods (note: located in your Unit Kit), pages 6–10

Lesson 3.3

  • Activity 4, Step-by-step tab and Ecosystem Restoration Simulation

Lesson 3.4

  •  Activity 2, Step-by-step tab, Possible Responses tab, On-the-Fly Assessment (hummingbird icon), and Ecosystem Restoration Simulation

Lesson 3.5

  • Activity 2, Step-by-step tab and Teacher Support tab (“Instructional Suggestion, Going Further: Balance and Interdependence of Ecosystems: Impacts of Invasive Species”)
  • Student bookRestoration Case Studies (note: located in your Unit Kit), pages 11, 31, and 47

Lesson 3.6

  • Activity 2, Step-by-step tab (especially steps 4–5), Possible Responses tab, and Critical Juncture Assessment (hummingbird icon)

Lesson 3.7

  • Activity 1, Step-by-step tab, Possible Responses tab, and Ecosystem Modeling Tool (Box 5 on student apps page, “3.7 No Decomposers Model”)

Looking for help?

Contact your Rochester Account Executive:

Jennifer Fosegan
(585) 590-4200
jfosegan@amplify.com

Amplify Science 6–8 Review Toolkit

Simplify your science curriculum review journey with the Amplify Science Review Toolkit. Within this Toolkit, you’ll find program overview information, classroom videos, evaluation rubrics, and a free sample unit.

Amplify Science for grades K–8 has been rated all-green by EdReports. Read the review on EdReports.

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What is Amplify Science?

A collaboration between the curriculum experts at UC Berkeley’s Lawrence Hall of Science and instructional technology experts at Amplify, Amplify Science is a comprehensive program that blends literacy-rich activities, hands-on investigations, and interactive digital tools. Amplify Science empowers students to think, read, write, and argue like 21st-century scientists and engineers. Highly adaptable and user-friendly, the program gives schools and individual teachers flexibility with their technology resources and preferences.

The program is backed by gold-standard research and is currently used by thousands of teachers across the US.

See Amplify Science in action

Amplify Science in Action: a week in the life (6–8)

What does a week in the life of an Amplify Science teacher look like? We asked Amy Trujillo, a sixth-grade teacher from Denver Public Schools, to talk through an example of what one week of using Amplify Science is like in her classroom.

In Amplify Science, students take on the role of a scientist or engineer to actively investigate compelling phenomena through engaging hands-on investigations, immersive digital simulations, comprehensive reading and writing activities, and lively classroom discussions.

See what Amplify Science looks like in a classroom with more topical videos:

Dig deeper into the curriculum

Amplify Science is rooted in the research-based Do, Talk, Read, Write, Visualize model of learning. Students engage with science and engineering practices, figure out disciplinary core ideas, and utilize and apply crosscutting concepts in multiple modalities across thoughtful, structured lessons, all centered around engaging anchor phenomena. Learn more about how a unique mix of activities and modalities provide students with multiple points of entry into the instruction.

Attend a webinar

Join the Lawrence Hall of Science for a series of free webinars! Curriculum experts will explore why embedded engineering and phenomena-based science instruction deliver results, with examples from Amplify Science.

Webinars are scheduled throughout the spring, and you can always sign to watch a recording if you’re unable to attend live.

Register for a webinar now!

Review rubrics

Using an evaluation rubric to review? Take a look at our filled-out TIME and EQuIP rubrics.

Test drive the program

Click submit to access a free sample unit from our middle school curriculum.

What’s included in our literacy curriculum for 6–8

Amplify ELA is a blended literacy curriculum designed specifically for grades 6–8. The heart of every lesson is the text. Our core English Language Arts curriculum enables teachers to teach skills through texts and develop their students’ muscles for building meaning through reading. With Amplify ELA, students learn to attack any complex text and make observations, grapple with interesting ideas, and find relevance for themselves.

Year at a glance

Each grade includes six core units centered on literary or informational texts, delivered in several forms of media. In addition to these main units, students will engage with targeted Grammar lessons and a dedicated Story Writing unit, plus two to three immersive learning experiences called Quests.

Grade 6 core units

Dahl & Narrative

1 assessment lesson
4 sub-units | 28 lessons | 4-6 weeks

A man with a mustache looks through a microscope at a slide, with abstract yellow lines in the background.

Mysteries & Investigations

1 assessment lesson
5 sub-units | 32 lessons | 4-6 weeks

A man with a mustache looks through a microscope at a slide, with abstract yellow lines in the background.

The Chocolate Collection

1 assessment lesson
5 sub-units | 25 lessons | 4-6 weeks

The Greeks

Myth World Quest

1 assessment lesson
4 sub-units | 25 lessons | 4-6 weeks

A man with a mustache looks through a microscope at a slide, with abstract yellow lines in the background.

Summer of the Mariposas

1 assessment lesson
2 sub-units | 27 lessons | 4-6 weeks

A man with a mustache looks through a microscope at a slide, with abstract yellow lines in the background.

The Titanic Collection

1 assessment lesson
5 sub-units | 25 lessons | 4-6 weeks

Grade 7 core units

A man with a mustache looks through a microscope at a slide, with abstract yellow lines in the background.

Red Scarf Girl

1 assessment lesson
4 sub-units | 31 lessons | 4-6 weeks

A man with a mustache looks through a microscope at a slide, with abstract yellow lines in the background.

Character & Conflict

1 assessment lesson
4 sub-units | 29 lessons | 4-6 weeks

A man with a mustache looks through a microscope at a slide, with abstract yellow lines in the background.

Brain Science

Perception Academy Quest

1 assessment lesson
4 sub-units | 25 lessons | 4-6 weeks

A man with a mustache looks through a microscope at a slide, with abstract yellow lines in the background.

Poetry & Poe

The “Who Killed Edgar Allen Poe” Quest

1 assessment lesson
5 sub-units | 29 lessons | 4-6 weeks

A man with a mustache looks through a microscope at a slide, with abstract yellow lines in the background.

The Frida & Diego Collection

1 assessment lesson
5 sub-units | 25 lessons | 4-6 weeks

A man with a mustache looks through a microscope at a slide, with abstract yellow lines in the background.

The Gold Rush Collection

1 assessment lesson
5 sub-units | 25 lessons | 4-6 weeks

Grade 8 core units

A man with a mustache looks through a microscope at a slide, with abstract yellow lines in the background.

Perspectives & Narrative

1 assessment lesson
4 sub-units | 27 lessons | 4-6 weeks

A man with a mustache looks through a microscope at a slide, with abstract yellow lines in the background.

Liberty & Equality

1 assessment lesson
6 sub-units | 38 lessons | 4-6 weeks

A man with a mustache looks through a microscope at a slide, with abstract yellow lines in the background.

Science & Science Fiction

1 assessment lesson
3 sub-units | 29 lessons | 4-6 weeks

A man with a mustache looks through a microscope at a slide, with abstract yellow lines in the background.

Shakespeare’s Romeo & Juliet

1 assessment lesson
2 sub-units | 22 lessons | 4-6 weeks

A man with a mustache looks through a microscope at a slide, with abstract yellow lines in the background.

The Holocaust: Memory & Meeting

1 assessment lesson
6 sub-units | 21 lessons | 4-6 weeks

A man with a mustache looks through a microscope at a slide, with abstract yellow lines in the background.

The Space Race Collection

1 assessment lesson
5 sub-units | 25 lessons | 4-6 weeks

Units at a glance

Amplify ELA lessons follow a structure both grounded in regular routines and flexible enough to allow for a variety of learning experiences. Lesson structures vary from day to day, ensuring that students are always engaged.

Learn more in the Amplify ELA Grade Overview.

Unit 6A

Dahl & Narrative

Students begin with narrative writing to develop foundational Focus skills and establish key classroom routines. Teachers use this work to create targeted feedback cycles and build a vibrant community centered on diverse experiences. Students then apply observational skills to Roald Dahl’s Boy: Tales of Childhood, learning to work closely with textual evidence.

Unit 6B

Mysteries & Investigations

Students read like an investigator to embark on a multi-genre study into the mesmerizing world of scientific and investigative sleuthing. The Secret of the Yellow Death: A True Story of Medical Sleuthing by Suzanne Jurmain, and Sir Arthur Conan Doyle’s Sherlock Holmes stories take place in the late 19th century, when medical diagnostics and criminal investigations were still evolving into scientific fields.

Unit 6C

The Chocolate Collection

Students explore primary documents and research the diverse cultural roles chocolate has played over 3,700 years, from its various uses in ancient Mexico to issues with modern production. Along the way, they build information literacy skills, craft research questions, and collaborate in Socratic seminars. Students also learn how to construct an evidence-based argument and use those skills to write pieces aimed at convincing readers about chocolate preferences, school lunch policies, and recommendations for local candy stores.

Unit 6D

The Greeks

Students closely explore and analyze three stories from Greek mythology: “Prometheus,” “Odysseus,” and “Arachne.” Drawing on the routines and skills established in previous units, these lessons ask students to move from considering the state of a single person to contemplating broader questions concerning the role people play in the world and the various communities they inhabit.

Unit 6E

Summer of the Mariposas

Students read Summer of the Mariposas by Guadalupe García McCall, a contemporary Latino retelling of The Odyssey. Following five sisters on their journey into Mexico and back, students explore this reimagining of the hero’s journey as they encounter Mexican folklore and Aztec legends along the way. Students analyze character development, compare the novel to Homer’s original, research Aztec mythology, explore symbolism, and engage in collaborative discussions before writing an essay about what makes the heroes successful.

Unit 6F

The Titanic Collection

Students explore primary documents and conduct research to understand the 1912 Titanic disaster, building information literacy skills by examining artifacts such as dining menus, ship photos, telegraph transcripts, and newspaper accounts. Each student is assigned a passenger from the manifest and writes a narrative account from that person’s perspective, considering different views. Students also participate in Socratic seminars to examine the complicated issues within the Titanic story.

Unit 7A

Red Scarf Girl & Narrative

Students begin with narrative writing to develop foundational Focus skills while teachers establish targeted feedback cycles and build a classroom community centered on diverse experiences. After exploring how they describe their own experiences and emotions, students apply the same close attention to analyzing details in Ji-li Jiang’s Red Scarf Girl: A Memoir of the Cultural Revolution.

Unit 7B

Character & Conflict

Students analyze characters’ responses to conflict and examine how authors use character interactions to develop theme and perspective. They read Carson McCullers’ “Sucker” and Lorraine Hansberry’s A Raisin in the Sun, both texts that explore how families facing hardships can support and harm one another. Students observe complex character growth and discuss issues of identity, family obligations, and differing notions of success.

Unit 7C

Brain Science

Students explore narrative nonfiction and informational texts about brain science to understand what it means to be human and how their developing brains impact daily experiences. They also build awareness of their cognitive strengths and analyze the structures of informational texts and scientific arguments. Key texts include Phineas Gage, Inventing Ourselves: The Secret Life of the Teenage Brain, and Oliver Sacks’ The Man Who Mistook His Wife for a Hat.

Unit 7D

Poetry & Poe

Students learn visualization techniques to read like a movie director, beginning with poems by D.H. Lawrence, Federico García Lorca, and Emily Dickinson to form mental images. They then read three Edgar Allan Poe texts, creating storyboards and analyzing narrative elements to learn about unreliable narrators. Students also participate in the murder-mystery Quest “Who Killed Edgar Allan Poe?” and write an essay arguing whether they can trust a narrator in the unit’s texts.

Unit 7E

The Frida & Diego Collection

Students explore primary source documents and research on Mexican artists Diego Rivera and Frida Kahlo, learning how they drew inspiration from Latin American folklore, politics, and customs. Along the way, students build information literacy by generating research questions and visual analysis skills through close reading of key paintings. They also compare the artists’ descriptive writing to Shakespeare’s and analyze figurative language. The unit culminates in a research project showcasing their interpretation of Frida and Diego’s work and legacy.

Unit 7F

The Gold Rush Collection

Students explore primary documents and conduct research on the California Gold Rush, building information literacy skills and constructing research questions. They also learn about the diverse people who participated, compare fictional and historical accounts, and participate in Socratic seminars. Students write narrative accounts from specific perspectives and complete a culminating research assignment combining essay and media project elements.

Unit 8A

Perspectives & Narrative

Students learn to read like writers, paying attention to craft and writing moves that shape reader experience and developing Focus and Showing skills as they build collaborative classroom routines. Students study three narrative texts, exploring themes of belonging and identity through close reading. They also practice alternating between analytic and narrative writing, and conclude with an essay arguing whether the mothers in Amy Tan’s “Fish Cheeks” are role models. 

Unit 8B

Liberty & Equality

Students study Civil War-era writings that debate the meaning of “all men are created equal,” exploring various perspectives on American ideals. Key texts include Walt Whitman’s Leaves of Grass, Frederick Douglass’ Narrative, and Harriet Ann Jacobs’s Incidents in the Life of a Slave Girl. The unit culminates with an essay examining Douglass’s arguments and Lincoln’s Gettysburg Address to consider what America means by “all men are created equal.”

Unit 8C

Science & Science Fiction

Students read Gris Grimly’s Frankenstein, a graphic novel adaptation of Mary Shelley’s novel, exploring themes of creator responsibility, societal influence, and the risks of scientific inquiry. They trace Victor’s sympathy for his creation, rewrite scenes from the creature’s perspective, and debate whether Victor owes the creature a companion. The unit concludes with an essay determining whether the creature should be considered human.

Unit 8D

Shakespeare’s Romeo & Juliet

Students read five excerpts from Shakespeare’s Romeo and Juliet to learn key elements of Shakespearean English through close reading. They practice memorizing and reciting the famous “Prologue,” put on stage performances, translate Shakespeare’s language into contemporary terms, and study the Shakespearean sonnet form. The unit concludes with an essay arguing whether love or hate is responsible for Romeo’s death.

Unit 8E

Holocaust: Memory & Meaning

Students use close reading to explore memoirs and primary sources that address two key Holocaust questions: How do societies become participants in atrocity, and what are our responsibilities as witnesses? Students analyze multiple perspectives through texts, including Alexander Kimel’s “I Cannot Forget,” Irene Butter’s Shores Beyond Shores, 1936 Olympics propaganda, and excerpts from Maus and Night.

Unit 8F

The Space Race Collection

Students explore primary documents and conduct research on the Space Race. They build information literacy skills, construct research questions, and learn about diverse participants from Soviet cosmonauts to American heroes like Buzz Aldrin and Katherine Johnson. Each student researches an assigned cosmonaut or astronaut and writes space blog entries from their perspective. Students also complete a capstone research essay and media project.

Print & digital components

The program includes instructional guidance and student materials for a year of instruction, with lessons and activities that keep students engaged every day.

A diagram shows the Amplify ELA curriculum with examples of the digital teacher edition on a tablet, print teacher edition pages, and a teacher projection of an artwork on a screen.

Teacher materials

Teacher Edition

Available digitally and in print, the Teacher’s Edition contains all the information teachers need to facilitate classroom instruction, including detailed lesson plans, video teacher tips, presentation slides, standards alignment, Exit Tickets, real-time differentiation strategies, and robust reporting.

Student materials

Student Edition

Available digitally and in print, student materials guide middle schoolers through complex texts and writing by engaging them with high-quality narrative and informational texts—providing videos, audio supports, and a digital experience that captures their attention. They also keep all of their writing in one place with a personal Writing Journal.

A collection of Amplify ELA materials including a print student edition, a digital student edition on a laptop, a writing journal, and an Arachne literature module.

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English language arts curriculum for middle school

With Amplify ELA, students learn to tackle any complex text and make observations, grapple with interesting ideas, and find relevance for themselves.

Rated all-green on EdReports, Amplify ELA earned perfect scores across all gateways. Para la versión en español, haga clic aquí.

Access sample

Easy and adaptable to teach

With six levels of embedded differentiation and assessments, teachers can make sure students are gaining key skills while not interrupting instruction. Because the program does this work in the background, teachers have more time doing what they love.

Also, only Amplify offers the 100-Day Pathway, a built-in guide to covering required content for each grade level in just 100 days while allowing teachers to add supplemental lessons and activities.

Knowledge Matters in Middle School

Amplify ELA has been recognized by the Knowledge Matters Campaign as a high-quality, knowledge-building literacy curriculum.

The Campaign highlights Amplify ELA as a program that infuses wonder and excitement into every learning experience—forging connections across grade levels and providing comprehensive support for both students and educators.

Read more on Knowledge Matters.

Our approach

Through its engaging digital program, powerful differentiation and assessment tools, and step-by-step instructional guides, our curriculum responds directly to the challenges and opportunities faced by middle school students and teachers.

See the research behind the program.

We empower students to become critical thinkers.

With text always at the center, students are encouraged to make ideas and opinions about meaning for themselves. Rather than focusing on right or wrong answers, they develop ideas and opinions on relevant, real-world, texts.

A student sits at a desk reading a textbook in a classroom, part of the Amplify ELA program, with other students and educational posters visible in the background.
Two students sit at desks in a classroom, looking forward with laptops open in front of them. Classroom posters and a whiteboard are visible in the background.

We provide six levels of differentiated support.

Multiple entry points and six levels of embedded differentiated support allow every student, regardless of fluency or ability level, to engage with the same complex texts and curriculum.

We assess while you instruct.

Embedded assessments and reports provide insight into each student’s progress without having to interrupt daily instruction. With data being collected at every learning moment, teachers can respond to student needs faster than ever before.

A teacher in a red polo shirt helps a student with curly hair in a classroom, both looking at open textbooks; educational posters hang on the wall behind them.
A student using a laptop

Amplify your teaching with ELA PD!

Amplify ELA offers targeted professional development (PD) sessions designed to optimize teaching strategies, enhance student engagement, and ensure effective curriculum delivery. Gain insights and techniques to make the most of your instructional time.

Explore ELA PD

Free download

Discover principles of true engagement in middle school ELA

Download

What’s included

Amplify ELA is a rigorous core curriculum that empowers teachers and engages middle school students.

Student Edition

Available digitally and in print, the student materials guide middle schoolers through complex texts and writing by:

  • Engaging students with high-quality narrative and informational texts.
  • Providing videos, audio supports, and digital experiences that capture their attention.
  • Keeping all of their writing in one place with a personal Writing Journal.

Teacher Edition

Available digitally and in print, the Teacher Edition contains all the information teachers need to facilitate classroom instruction, including:

  • Detailed lesson plans.
  • Video teacher tips embedded in the lesson.
  • Standards alignment and exit tickets.
  • Real-time differentiation strategies.
  • Robust reporting.

Interactive Quests

Quests are fun, week-long immersions into a specific, multilayered topic. They enable students to practice analytical reading, writing, speaking, and listening skills—all while building a strong classroom community.

Digital library for independent reading

The expansive Amplify Library includes more than 700 digital fiction, nonfiction, classic, and contemporary titles.

Amplify ELA makes teachers’ lives easier

Our program ensures that standards are covered, skills are taught, and students are prepared with proper scaffolding and encouragement.

  • Embedded differentiation to support all readers.
  • Informative and streamlined assessment system.
  • Robust reporting that tracks progress.
  • Powerful feedback tools.
All materials

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Welcome, Amplify ELA families!

We’re excited to welcome you and your student to the Amplify ELA program for the new school year, and to provide you with exceptional learning opportunities through ELA. We’ve assembled the following resources and guides to help you support your student and enable them to have the most productive experience with our platform throughout the year.

Para la versión en español, haga clic aquí.

Illustrated collage with people playing sports, riding bikes, and a thoughtful person’s portrait, framed by natural elements and a rocket launching, next to an "EdReports Review Year 2020" badge.

What is Amplify ELA?

Amplify ELA helps students in grades 6–8 read and understand complex texts that encourage them to grapple with interesting ideas and find relevance for themselves. Amplify ELA is a blended program that includes both digital and print materials, but can also be used as a print-only version. Students using Amplify ELA read text passages closely, interpret what they find, discuss their thinking with peers, and develop their ideas in writing. The lesson structure is easy to follow, but flexible enough to allow for a variety of learning experiences and varied enough to keep students engaged. 

Features include:

  • Functionality that allows individual students to work at their own level while also being challenged appropriately.
  • Built-in tools that allow teachers to track and respond to student work.
  • The digital Amplify Library, which contains more than 700 downloadable, full-length fiction and nonfiction books.
  • The Vocab App, which uses game-like activities to help students master keywords from the program’s texts. (Students using print materials will see keywords highlighted.)
  • Independent writing assignments called Solos, available on mobile devices.
  • Interactive projects called Quests that accompany certain units to provide additional practice with analytical reading, writing, speaking, and listening skills.

Getting started

How you can support the child in your care:

  • If possible, read with your student daily; even 15 minutes of reading together each day can make a huge impact. You can read aloud sections of the text together—many middle grade students enjoy performing sections of dialogue by taking on the role of a character in a play, or adding some dramatic flair to a poem with which they are working. If your student struggles with reading aloud, you might try reading the text to them with expression, then having them read it back to you. For additional practice, there are an array of fluency activities in the program’s Flex Days. Ask your student to help you find these activities.
  • Find moments to discuss what they are reading and discovering. Examples of questions you could ask: What stood out to you from what you read today? Were any sentences or words confusing? What was most surprising? What do you think the writer was trying to communicate? Do you agree with the writer’s ideas or descriptions? What connections can you make between what you are reading and your own life, or other issues you’ve heard about?
  • Listen to your student read their written responses or have them share with a friend over the phone or video chat. 
  • Browse the Amplify Library with your student to find books they’ll enjoy and be able to read fluently and independently.
  • Review this Protecting Kids Online website by the Federal Trade Commission addressing digital safety.

Accessing texts in the Amplify Library

We encourage students to utilize the core texts from the Amplify Library while at home! Please follow these steps to download a text for offline reading:

1. Navigate to the Program & Apps menu at the top of your screen and scroll through to find the Amplify Library icon. When you select it, the Amplify Library will open in a new tab.

A digital menu displays various educational tools and resources, with "Amplify ELA" highlighted at the top and the "Library" option outlined in orange.

2. If prompted, follow the directions to set up a pin for the Amplify Library; otherwise, proceed to the next step.

A pop-up window prompts the user to create a four-character PIN of lowercase letters and/or numbers for offline reading, with Cancel and Submit buttons.

3. In the upper right corner of your screen, search for the book you would like to download. Example: The Secret of the Yellow Death: A True Story of Medical Sleuthing.

A digital library search page displays "yellow death" in the search bar with no results found for title, authors, or genre. Book covers are visible in the left sidebar.

4. Select the Download button.

A digital library interface displays the book "The Secret of the Yellow Death" by Suzanne Jurmain, showing its cover, synopsis, and options to read or download.

5.  If you lose connection while still in the Amplify Library, you can continue to access and read the downloaded book(s). If the page refreshes without internet access, or you try to login on another device without internet access, you will lose access to the downloaded book(s) until the internet connection is restored. 

To retrieve your downloaded texts: 

  1.  In the Amplify Library app, open the My Library drop-down menu in the upper left corner.
  2. Select Downloaded. 
  3. Choose the text you wish to read from all of your pre-downloaded texts.
A dropdown menu under "My Library" shows options: Recently Read, Favorites, Downloaded (highlighted), and All Books. Below, a Recently Read section displays three book covers.

Materials overview

Not every school will operate the same way, but students attending schools that have both the print and digital editions of the program will likely have the following print materials at home:

  • Student Edition: This includes all of the readings and activities necessary for instruction throughout the year. Students can read the selections both digitally and in print, annotating in either format. The lessons in the print Student Edition reflect each digital lesson, but have been modified to work effectively in print. 
  • Writing Journals: This provides space for students to respond to Writing Prompts and complete other written assignments. 

In the case that students are without access to devices or the internet, they can continue to complete key reading and writing assignments using the print Student Editions and student Writing Journals.

Teachers can also access, print, and mail student Novel Guides for up to 12 commonly taught novels. Six of these novels are available in the Amplify Library, and most should be available in a public library.

Unit overviews

Below are quick overviews of each unit your student will be working through in their grade throughout the year. Included along with each unit is a downloadable guide that provides a more in-depth look at what content is covered and how you can help your student advance their understanding of the topics.

  • Unit 6A: Dahl & Narrative  
    • Students begin with narrative writing to quickly boost their writing production, learn the foundational skill of focus, and become comfortable with key classroom habits and routines they will use all year. Students then apply their new observational focus to some lively readings from Roald Dahl’s memoir Boy and learn how to work closely with textual evidence.
  • Unit 6B: Mysteries & Investigations
    • Students read like an investigator to embark on a multi-genre study of the mesmerizing world of scientific and investigative sleuthing. At the end of the unit, students write an essay explaining which trait is most useful to problem-solving investigators.
  • Unit 6C: The Chocolate Collection
    • The Aztecs used it as currency. Robert Falcon Scott took it to the Antarctic. The Nazis made it into a bomb designed to kill Churchill. The 3,700-year-long history of chocolate is full of twists and turns, making it a rich and rewarding research topic. In this unit, students explore primary source documents and conduct independent research to better understand the strange and wonderful range of roles that chocolate has played for centuries around the world.
  • Unit 6D: The Greeks
    • Greek myths help us understand not only ancient Greek culture but also the world around us and our role in it. Drawing on the routines and skills established in previous units, these lessons ask students to move from considering the state of a single person—themselves or a character—to contemplating broader questions concerning the role people play in the world and the communities they inhabit within it.
  • Unit 6E: Summer of Mariposas
    • The borderlands between the United States and Mexico are the place of legends, both true and fictional. Summer of the Mariposas, by Guadalupe Garcia McCall, plants a retelling of the Odyssey into this setting, launching five sisters on an adventure into a world of heroes and evildoers derived from Aztec myths and Latinx legends. On the journey, the sisters reconcile the dissolution of their parent’s marriage and find new strength in their identity and connection to Aztec lineage. Students consider how McCall uses the structure of the hero’s journey to celebrate women, heritage, and a broad definition of family. Students also have the opportunity to compare these characters’ fictional journey into Mexico to a description of one boy’s true journey into the United States.
  • Unit 6F: The Titanic Collection 
    • In this research unit, students learn to tell the difference between primary, secondary, and tertiary sources; determine if a given source is reliable; and understand the ethical uses of information. Students then construct their own research questions and explore the internet for answers. They also take on the role of a passenger from the Titanic’s manifest to consider gender and class issues as they research and write narrative accounts from the point of view of their passenger.  
  • Unit 6G: Beginning Story Writing
    • In this unit, students get to practice their creative writing skills and learn the elements of storytelling and character development, as well as the importance of vivid language. Students gain a sense of ownership over their writing as they experiment with the impact of their authorial choices on sentences, language, character traits, and plot twists.
  • Grade 6: Grammar
    • In this unit, students complete self-guided grammar instruction and practice that teachers assign to them throughout the year. Sub-units are organized by key grammar topics, so teachers can assign the content that best meets their student’s needs while making sure students work with the key grammar topics for their grades.
  • Unit 7A: Red Scarf Girl & Narrative
    • In this study of a highly engaging memoir of a young woman growing up in China during the Cultural Revolution, students quickly learn the history and politics of this tumultuous period by focusing on the story of someone living through the upheaval. As students follow her journey through a world turned upside down, they will track the changes in her feelings and motivations over time.
  • Unit 7B: Character & Conflict
    • By reading the play A Raisin in the Sun and the short story “Sucker,” students explore how people facing hardships can inflict unintentional harm on the people around them. The two narratives work together to provide opportunities for students to analyze characters’ responses to conflict and the author’s development of ideas over the course of a piece of fiction.
  • Unit 7C: Brain Science
    • Could you survive an iron rod through your skull? Phineas Gage did, and his gruesome-but-true story allows students to build background information and analyze other informational texts, including the contemporary The Man Who Mistook His Wife For A Hat and the relevant Demystifying the Adolescent Brain.
  • Unit 7D: Poetry & Poe
    • Poe’s texts always offer so much to notice, decipher, talk about—and creep us out. Since things are not always what they seem, students must use close reading skills to question whether they should believe what Poe’s narrator is telling them … or not.
  • Unit 7E: The Frida & Diego Collection
    • Mexico’s most famous and provocative artists, Diego Rivera and Frida Kahlo, were an extraordinary couple who lived in extraordinary times. They were both soul mates and complete opposites. Their multifaceted lives and work offer students rich and fascinating subjects to study as they examine primary source documents and conduct independent research.
  • Unit 7F: The Gold Rush Collection
    • In this research unit, students choose from a large collection of primary and secondary sources to learn about the wide range of people who took part in the California Gold Rush. They also take on the role of someone who lived during the gold rush and write journal entries from their perspective.
  • Unit 7G: Intermediate Story Writing
    • In this unit, students get to practice their creative writing skills and learn the elements of storytelling and character development, as well as the importance of vivid language. Students gain a sense of ownership over their writing as they experiment with the impact of their authorial choices on sentences, language, character traits, and plot twists.
  • Grade 7: Grammar
    • In this unit, students complete self-guided grammar instruction and practice that teachers assign to them throughout the year. Sub-units are organized by key grammar topics, so teachers can assign the content that best meets their student’s needs while making sure students work with the key grammar topics for their grades.
  • Unit 8A: Perspectives & Narrative
    • This unit aims to teach students to read like writersThey practice paying attention to the craft of writing and to the moves a good writer makes to shape the way we see a scene or feel about a character—to stir us up, surprise us, or leave us wondering what will happen next. Students closely read examples of rich, layered narrative nonfiction, analyze the techniques each author uses to make their writing resonate, and practice applying these techniques to their own narrative writing.
  • Unit 8B: Liberty & Equality
    • In this unit, students look at the words of a range of creators—from poet Walt Whitman to abolitionist Frederick Douglass to President Abraham Lincoln—to see how their writing contributed to an extreme shift in social organization: a whole new concept of what it means for people to be considered “equal.” They also study multiple perspectives on the Civil War, including the memoir of a girl who was enslaved, a confederate girl’s diary, and a nonfiction account of the young boys who served as soldiers during the war. 
  • Unit 8C: Science & Science Fiction
    • Students read Gris Grimly’s Frankenstein, a graphic novel that adds captivating illustrations to an abridgment of the 1818 edition of Mary Shelley’s book. Paired with Shelley’s text, Grimly’s haunting—and, at times, horrific—representations of Frankenstein’s creature push students to wrestle with some of the text’s central themes: the source of humanity and the root of evil. Students then write an essay in which, after arguing both sides of the question, they determine whether or not Frankenstein’s creature should ultimately be considered human.
  • Unit 8D: Shakespeare’s Romeo & Juliet
    • Romeo and Juliet combines romance with action, offering a wide range of themes and scenes for students to read about and act out. Your middle schoolers are at the right age to identify with the lovers’ strong feelings—and also old enough to think critically about the choices Romeo and Juliet make.
  • Unit 8E: Holocaust: Memory & Meaning
    • This unit uses a range of primary source articles, images, and videos, as well as literary nonfiction and graphic nonfiction, to study what made the atrocities of the Holocaust possible. Students investigate how propaganda was generated and employed to create a political environment that ultimately corrupted a society. The Olympics are seen through the lens of an international propaganda campaign, providing cover for Nazis to begin eliminating non-Aryans from their culture. The final sub-unit examines the outcomes of Nazi doctrine and the impact on Jewish victims and survivors.
  • Unit 8F: The Space Race Collection
    • In this unit, students to put their research and close-reading skills to the test to distinguish between reliable  and unreliable sources, explore primary documents, and conduct independent research to better understand the space race that took place between two of the world’s superpowers. This dramatic story offers students a rich research topic to explore as they build information literacy skills, learn how to construct their own research questions, and explore the internet for answers.
  • Grade 8: Grammar
    • In this unit, students complete self-guided grammar instruction and practice that teachers assign to them throughout the year. Sub-units are organized by key grammar topics, so teachers can assign the content that best meets their student’s needs while making sure students work with the key grammar topics for their grades.
  • Unit 8G: Advanced Story Writing
    • In this unit, students get to practice their creative writing skills. They’ll learn the elements of storytelling and character development, and the power of vivid language to grab readers and pull them into a story.

Additional activities

Quests: 

You may notice your student working with peers on the same interactive project over several days, trying to solve a mystery or explain a historical event. That’s what happens when a teacher assigns a Quest: an in-depth week-long exploration that requires collaboration and deepens engagement with texts and topics.

Vocab App:

The Vocab App helps students master vocabulary words through game-like activities that challenge them to think through morphology, analogy, and synonyms/antonyms, and to decipher meaning through context.

Have a question about Amplify ELA?

Visit our help library to search for articles with answers to your program questions. 

For additional curriculum support, please contact your student’s teacher.

Amplify Science 6–8 Review Toolkit

Simplify your NGSS curriculum review journey with the Amplify Science Review Toolkit. Within this Toolkit, you’ll find program overview information, classroom videos, evaluation rubrics, and a free sample unit.

Amplify Science for grades K–8 has been rated all-green by EdReports. Read the review on EdReports.

image of Amplify Science and science classroom materials for science teachers

What is Amplify Science?

Built from the ground up for the Next Generation Science Standards at UC Berkeley’s Lawrence Hall of Science, Amplify Science is a comprehensive program that blends literacy-rich activities, hands-on investigations, and interactive digital tools to empower students to think, read, write, and argue like 21st-century scientists and engineers. Highly adaptable and user-friendly, the program gives schools and individual teachers flexibility with their technology resources and preferences.

The program is backed by gold-standard research and is currently used by thousands of teachers across the US.

See Amplify Science in action

Amplify Science in Action: a week in the life (6–8)

What does a week in the life of an Amplify Science teacher look like? We asked Amy Trujillo, a sixth-grade teacher from Denver Public Schools, to talk through an example of what one week of using Amplify Science is like in her classroom.

In Amplify Science, students take on the role of a scientist or engineer to actively investigate compelling phenomena through engaging hands-on investigations, immersive digital simulations, comprehensive reading and writing activities, and lively classroom discussions.

See what Amplify Science looks like in a classroom with more topical videos:

Dig deeper into the curriculum

Amplify Science is rooted in the research-based Do, Talk, Read, Write, Visualize model of learning. Students engage with science and engineering practices, figure out disciplinary core ideas, and utilize and apply crosscutting concepts in multiple modalities across thoughtful, structured lessons, all centered around engaging anchor phenomena. Learn more about how a unique mix of activities and modalities provide students with multiple points of entry into the instruction.

Attend a webinar

Join the Lawrence Hall of Science for a series of free webinars! Curriculum experts will explore why embedded engineering and phenomena-based science instruction deliver results, with examples from Amplify Science.

Webinars are scheduled throughout the spring, and you can always sign to watch a recording if you’re unable to attend live.

Register for a webinar now!

Review rubrics

Using an evaluation rubric to review? Take a look at our filled-out TIME and EQuIP rubrics.

Test drive the program

Click submit to access a free sample unit from our middle school curriculum.

Amplify Science K–5 Review Toolkit

Simplify your NGSS curriculum review journey with the Amplify Science Review Toolkit. Within this Toolkit, you’ll find program overview information, classroom videos, evaluation rubrics, and a free sample unit.

What is Amplify Science?

Built from the ground up for the Next Generation Science Standards at UC Berkeley’s Lawrence Hall of Science, Amplify Science is a comprehensive program that blends literacy-rich activities, hands-on investigations, and interactive digital tools to empower students to think, read, write, and argue like 21st-century scientists and engineers. Highly adaptable and user-friendly, the program gives schools and individual teachers flexibility with their technology resources and preferences.

The program is backed by gold-standard research and is currently used by thousands of teachers across the US.

See Amplify Science in action

Amplify Science in Action: a week in the life (K–5)

What does a week in the life of an Amplify Science teacher look like? We asked Keneisha Charleston, a second-grade teacher from Chicago Public Schools, to talk through an example of what one week of using Amplify Science is like in her classroom.

In Amplify Science, students take on the role of a scientist or engineer to actively investigate compelling phenomena through engaging hands-on investigations, immersive digital simulations, comprehensive reading and writing activities, and lively classroom discussions.

See what Amplify Science looks like in a classroom with more topical videos:

Dig deeper into the curriculum

Amplify Science is rooted in the research-based Do, Talk, Read, Write, Visualize model of learning. Students engage with science and engineering practices, figure out disciplinary core ideas, and utilize and apply crosscutting concepts in multiple modalities across thoughtful, structured lessons, all centered around engaging anchor phenomena. Learn more about how a unique mix of activities and modalities provide students with multiple points of entry into the instruction.

Attend a webinar

Join the Lawrence Hall of Science for a series of free webinars! Curriculum experts will explore why embedded engineering and phenomena-based science instruction deliver results, with examples from Amplify Science.

Webinars are scheduled throughout the spring, and you can always sign to watch a recording if you’re unable to attend live.

Register for a webinar now!

Review rubrics

Using an evaluation rubric to review? Take a look at our filled-out TIME and EQuIP rubrics.

Test drive the program

Click submit to access a free sample unit from our elementary curriculum.

What is Amplify Science?

Built from the ground up for the Next Generation Science Standards at UC Berkeley’s Lawrence Hall of Science, Amplify Science is a comprehensive program that blends literacy-rich activities, hands-on investigations, and interactive digital tools to empower students to think, read, write, and argue like 21st-century scientists and engineers. Highly adaptable and user-friendly, the program gives schools and individual teachers flexibility with their technology resources and preferences.

The program is backed by gold-standard research and is currently used by thousands of teachers across the US.

See Amplify Science in action

Amplify Science in Action: a week in the life (6–8)

What does a week in the life of an Amplify Science teacher look like? We asked Amy Trujillo, a sixth-grade teacher from Denver Public Schools, to talk through an example of what one week of using Amplify Science is like in her classroom.

In Amplify Science, students take on the role of a scientist or engineer to actively investigate compelling phenomena through engaging hands-on investigations, immersive digital simulations, comprehensive reading and writing activities, and lively classroom discussions.

See what Amplify Science looks like in a classroom with more topical videos:

Dig deeper into the curriculum

Amplify Science is rooted in the research-based Do, Talk, Read, Write, Visualize model of learning. Students engage with science and engineering practices, figure out disciplinary core ideas, and utilize and apply crosscutting concepts in multiple modalities across thoughtful, structured lessons, all centered around engaging anchor phenomena. Learn more about how a unique mix of activities and modalities provide students with multiple points of entry into the instruction.

Attend a webinar

Join the Lawrence Hall of Science for a series of free webinars! Curriculum experts will explore why embedded engineering and phenomena-based science instruction deliver results, with examples from Amplify Science.

Webinars are scheduled throughout the spring, and you can always sign to watch a recording if you’re unable to attend live.

Register for a webinar now!

Review rubrics

Using an evaluation rubric to review? Take a look at our filled-out TIME and EQuIP rubrics.

Test drive the program

Click submit to access a free sample unit from our middle school curriculum.

Amplify Science

A new phenomena-based science curriculum for grades K–5.

Universal Design for Learning

Universal Design for Learning (UDL) is a research-based framework for improving student learning experiences and outcomes by focusing on careful instructional planning to meet the varied needs of students. UDL is not a special-education initiative. Through the UDL framework, the needs of all learners are considered and planned for at the point of first teaching, thereby reducing the need for follow-up or alternative instruction. Following the principles of UDL, Amplify Science units and lessons are designed to be universal and flexible in allowing choice; different paths toward goals; and multiple means of engagement, representation, action and expression, and assessment, so that all students have an opportunity to learn during lessons and be successful with lesson and unit goals. While Amplify Science lessons are intentionally designed to be universal and flexible, each student is unique and teachers will need to understand their students’ individual learning strengths and needs in order to refine or enhance lessons through differentiation strategies to make them truly universal. All lessons are designed with a range of students in mind, providing multiple points of entry and modalities of learning (e.g. talking to peers, viewing short explanatory videos, reading, writing, conducting investigations, etc.) for students to engage with the content. In addition, to support teachers with the decisions they need to make in order to ensure that all students have access to learning, each lesson contains a Differentiation Brief that outlines specific supports for diverse learners, as well as flexible options for adapting lessons according to students’ needs. UDL principles and guidelines, as well as practical suggestions for classroom teaching and learning, can be found at the National Center for UDL (udlcenter.org).

Differentiation strategies to support all students

Amplify Science provides a differentiated path for all students to thrive in the science and engineering classroom. Following the principles of UDL, lessons and Differentiation Briefs were designed to provide teachers with detailed guidance on supporting students with diverse learning strengths and needs, with a particular focus on English learners and long term English learners, standard English learners, students experiencing stressful living conditions (students living in poverty, foster youth, migrant students), advanced learners, girls and young women, students with disabilities, and students experiencing academic learning challenges.

The 5 patterns we found in schools with improved reading

After a decade of tracking students’ pathways in early reading, we’ve been able to identify the schools getting outsized results—so we called them to ask what they’re doing! And so far, we’ve identified five consistent patterns.

1. Start early.

Schools that deliver the strongest results work hard to get kids on track — and often ahead — in kindergarten. Why? Those who get through the decoding stage by age eight begin building vocabulary and background knowledge through reading itself. These schools reason that it’s easier to get students ahead from the start than to try to catch them up later.

2. Surround kids with books.

Reading at the right level improves decoding, vocabulary, knowledge, and stamina. In a recent study, 11 students who read an extra seven minutes per day in class had substantially higher reading rates than other students. Those minutes add up to 160,020 additional words read each school year, and reading volume is important in building knowledge—even more so than cognitive ability.

3. Measure.

All schools collect data; the best ones think of it as measurement. For instance, they measure whether an intervention is having the expected impact. If not, they introduce new, temporary measures for attendance, perhaps, or fidelity of implementation. They are constantly tinkering and learning. They describe themselves as never satisfied.

4. Create a support team.

One of the most effective practices we found is ensuring that students get extra support when they need it. Classroom teachers can have a hard time reaching everyone, even with the best intentions. A cross-classroom team can base its decisions on careful data analysis and do whatever it takes to ensure extra resources are found and allocated where they’re needed most.

5. Beat summer.

Summer is brutal. Students often lose as much as half of their hard-won gains from the school year over the summer weeks, and the loss is especially steep for students from lower-income households. But even a few minutes a week of reminder exercises can reverse these losses, just as using a muscle prevents atrophy.

Reading at a college-entry level is a virtuoso performance. Even reading on level by third grade requires a constellation of successes — from mastering the sound-spelling patterns of English, to the painstaking accumulation of vocabulary and knowledge necessary to make sense of sentences. The simple verb to read hardly feels adequate to describe what students are doing when they make sense of the text. Ensuring the effortless enjoyment of reading for all is one of the great social undertakings of our time. We’re so happy to be working toward this noble goal with you.

Four ways to engage middle-school students in ELA

You know how engaged middle-school students are—in their own emotions, relationships, and TikToks. How do you engage them in your ELA classroom?

It’s tough! It’s not just about holding their attention while they’re in class. We need to provide the kind of real engagement that leads to real learning.

Research confirms (not surprisingly) that getting middle schoolers ready for college and career depends on it, and requires a truly engaging ELA curriculum.

The stakes are high. Sixth-grade students who fail a literacy course are more than 50% more likely to not graduate from high school.

Yet, on average, middle-school ELA students spend less than 20% of class time engaged with the text. In a 50-minute class period, that’s only 10 minutes of text.

At Amplify, we believe greater engagement with text is key not only for ELA success, but for all academics. That’s why we created these four actionable principles of middle-school ELA engagement.

Middle-school is a moment—one we must seize.

First, here’s why middle schoolers require an approach and curriculum designed just for them.

Young people at middle-school age are becoming increasingly independent, and increasingly self-conscious. They need to feel respected and safe when they participate, especially when they make mistakes. They’re super focused on their peers, but they still depend on guidance from you.

There’s a lot going on in their worlds, and there’s a lot going on in their brains. In fact, early adolescence is the second-biggest stage of rapid brain development.

The development is happening largely in the prefrontal cortex. It’s the area that brain researcher Maryanne Wolf calls “the cognitive workspace.” When it comes to middle-school ELA curriculum, we want to use strategies that engage students in using their cognitive workspaces.

The 4 principles of middle-school engagement

We believe these four principles are most essential to engaging middle-school students in developing their literacy skills—and becoming confident, active learners.

  1. Enable all students to work up. Provide multiple entry points and scaffolds so that every student can find their way into a text or activity. Here are some differentiation strategies:
    1. Incorporate multimedia. Often a video dramatization or audio recording can help students connect with a complex text.
    2. Scaffold with passage previews, read-alongs, and questions that make students want to re-read.
    3. Don’t forget vocab! Daily practice makes a huge difference, especially with assignments designed to challenge students at their level.
  2. Provide just right feedback. At this age, it’s important for students to see opportunity rather than failure.
    1. Quick over-the-shoulder notes feel actionable and encouraging.
    2. Training all students to offer helpful comments creates a positive vibe around feedback.
    3. Focusing on specifics helps students know how to proceed and improve.
  3. Engage multiple modalities, especially collaboration. Students comprehend text in all sorts of ways—hearing, speaking, writing, seeing, performing, and more. Try alternate modalities like dramatic readings or debates, which also give students the benefits of working together.
  4. Promote critical thinking. This one’s the biggest idea beneath all the others.

To be fully engaged, middle schoolers need to know that their work is relevant and recognized. A truly engaging curriculum supports a range of observations and interpretations. Some approaches:

  1. Be clear that the text, not the teacher, has the answers. Ask questions like “How did you get to that response?” Help students follow this rule: If you can justify it in the text, you can hold on to your interpretation.
  2. Guide students to develop theories rather than get it right. For example, ask questions like “Why does (or doesn’t) this make sense?”
  3. Try the Socratic style. Emphasizing inquiry and discussion brings home the power of open-ended questions. It also positions the teacher as facilitator, not deliverer of all knowledge.

These principles won’t just help your students get through middle-school—they’ll help you get through to your middle schoolers.

Learn more.

Read more about Amplify ELA, including an overview of the components of the curriculum in grades 6–8.

Embracing artificial intelligence in the math classroom

Artificial intelligence seems to be everywhere these days. We use it when we ask Alexa or Siri for the morning weather report. We use it when GPS tells us how to best avoid traffic. We use it when we chill at the end of the day with a recommendation from Netflix. 

But what about during the day—and specifically, at school? Even more specifically, can AI be leveraged to enhance the math classroom? 

“While AI is an amazing tool, you’ve really got to make sure that you are focusing in on your expertise as well,” says veteran math educator and STEM instructional coach Kristen Moore, “And saying, ‘How can I use this to make something better?’ and not just, ‘How can I use this to make something?’” 

In this post, we’ll talk about the current state of AI in math education, and how it can support educators in making math better. (SPOILER: It’s not going to replace you!) 

First, some STEM learning for us: What is artificial intelligence? 

Artificial intelligence, or AI, refers to the development of computer systems able to perform tasks that typically require human intelligence. 

It involves creating algorithms and systems that enable computers to learn from data, adapt to new situations, and make decisions or predictions.

AI aims to mimic human cognitive functions such as understanding language, recognizing patterns, solving problems, and making decisions. It encompasses a range of techniques and technologies, including machine learning, neural networks, natural language processing, and robotics.

The term “artificial intelligence” was introduced in 1956.  The availability of vast amounts of data and advancements in computer power in the 2010s led to additional breakthroughs. And with the proliferation of smartphones, smart devices, and the internet, AI technologies began to work their way into our homes, cars, pockets, and everyday lives.

What’s the state of AI in education? 

AI is already commonplace in schools and classrooms. Here are just a few examples:

  • Adaptive learning: This software uses AI algorithms to adjust the difficulty and content of lessons based on a student’s performance, helping students remain engaged and challenged at their optimal level.
  • Assistive technologies: AI helps students with disabilities by providing assistive technologies like text-to-speech and speech-to-text tools, making educational content more accessible.
  • Plagiarism detection: These tools use AI algorithms to identify instances of copied or unoriginal content in students’ assignments, essays, and projects. 
  • Data analysis for teachers: AI analyzes data from student assessments to identify trends and insights, helping teachers make informed decisions about instructional strategies. It can also predict students’ performance trends, helping teachers identify at-risk students early and intervene to provide additional support.
  • Grammar, spelling, and style checkers: AI can provide real-time feedback to students (and teachers!) on their writing work.

Embracing AI technology in your math classroom

While AI is not here to replace teachers, it is here to stay. And experts say it’s only going to become more commonplace. But despite how common AI is already—both outside and inside school—not all teachers are familiar with its numerous applications and potential. Now is a great time for educators to start exploring its uses and get ahead of the curve.

Here are a few easy entry points for math teachers. 

ChatGPT: A common AI tool, ChatGPT is designed to understand and generate human-like text based on the input it receives. It’s trained on a wide range of internet text, which enables it to generate responses to a vast array of prompts and questions. 

Most students have likely experimented with ChatGPT, while teachers—though aware of it—are less likely to use it. ChatGPT has highly practical applications for both groups, though—including in the math (and science) classroom. 

It can, for example, help teachers plan interesting, relevant math lessons for their students. Kristen Moore, who discusses this topic on Math Teacher Lounge, suggests that math teachers use ChatGPT to:

  • Connect topics to student interests and vice-versa. (Teachers can ask ChatGPT for real-life applications of polynomials and select those that might pique student interest, or ask about math applications derived from students’ hobbies and pursuits.) 
  • Generate word problems (including step-by-step solutions), lessons, projects and rubrics, and more.

Toward the (near) future

As AI advances, it will continue to revolutionize education. Here are a few time-saving ways that educators can look forward to using it in their classrooms.

  • AI tutors: AI-powered virtual tutors will help math students with homework questions and provide explanations for various concepts. These tutors can be available at home 24/7, allowing students to seek an AI homework helper whenever they need it.
  • Automatic graders: Some AI tools can automatically grade math work, including multiple-choice and short-answer assignments. These tutors can be available at home 24/7 in any household with internet access, allowing students to seek more personalized instruction.
  • Personalized learning paths: These AI-powered platforms will work particularly well for math students by adapting to each student’s skill level and pace, offering tailored exercises and challenges that cater to their strengths and identify areas of improvement. They will analyze students’ performance and adjust the difficulty of content, ensuring that students get targeted support and opportunities to progress.

More to explore

To dive deeper into AI in math education—and get rolling with AI in your classroom—check out this two-episode mini-series on our Math Teacher Lounge podcast focused on just that: 

“I’m a believer that learning is inherently social,” says Carolan, who is quick to emphasize how technology can enhance that quality, not replace it. The same can be said for the role teachers play in the classroom—a role technology can support, but never take away. To learn more about this topic (and discuss it with your fellow educators!), head to our Math Teacher Lounge community

5 strategies to transform your math classroom

Want to shift your math teaching practices this year, but not sure where to start? That’s a good problem to have! 

You can boost your instruction this fall with problem-based learning, technology in the math classroom, and more—all in ways that put students at the center. 

“All students need the opportunity to feel like they can figure out mathematics,” says Jennifer Bay-Williams, Ph.D., an author and professor of mathematics education at University of Louisville. “That’s where they develop a math identity, [the idea] that they can do math. And they start feeling like, ‘I can figure this out.’” 

Bay-Williams spoke at our 2024 Math Symposium, along with other thought leaders and expert educators. Keep reading to see how their key takeaways can help you shift your math instruction this school year!

Center student ideas in a collaborative math classroom

Amplify Math Suite Executive Director Kristin Gray had great tips for teachers looking to center student ideas in the classroom. Simply put, it’s all about helping them make several types of connections. These can include any of the following: 

  • Connecting students’ classroom math experiences to real life
  • Connecting math ideas to one another
  • Connecting their ideas to the ideas of their classmates 

How do teachers foster these important connections? That’s where problem-based lessons come in. Rather than teaching a concept or formula in isolation, then having students practice it, try inviting students to collaborate on a real-life problem that will lead them to that math idea. (For example, you might ask them to work on designing a small traffic or subway system that requires developing ideas about distance, rate, and time.)

As a result, students build problem-solving skills collaboratively, feel their ideas are valued, develop their own ways to make math make sense, and learn from and with each other. Teachers also get to know and appreciate the different backgrounds and styles students bring to the classroom, opening up new opportunities for engagement—and connection. 

Reimagine student engagement

No matter how engaging you are as a teacher, it’s typically students who drive engagement—and that’s actually good news. You don’t have to reinvent the wheel or do somersaults to get their attention. In fact, a lot of engagement comes from creating routine and familiar opportunities for connection. And it can also come from allowing students to make mistakes. 

“We want all students to have an entry point into [math] tasks,” notes Amplify STEM Product Specialist James Oliver. “Those students that seem to always feel like they don’t fit or don’t have the identity in that math classroom, we want them to immediately have successes and have their curiosities tested.” Successes—and productive failures. “What we’ve learned is, you are not firing any synapses, nothing’s happening if you’re just getting it immediately correct.”

Nurture student curiosity

Which is better: letting students dive into a box of LEGO pieces to see what happens, or providing a step-by-step guide to building the airplane? 

It’s actually a tie. In both structured and loose approaches, the key is to spark curiosity and communication. “If we want them to be mathematicians, we should let them talk about math,” says Amplify Director of 6–12 Core Math Curriculum Kurt Salisbury, Ph.D. Here’s his 3D approach:

DISCOVER
Discovering the relationships among mathematical ideas is a key part of mathematical thinking. 

DESCRIBE
Students communicate their mathematical thinking by describing the processes, procedures, or relationships needed to work with a concept or pattern. 

DEVELOP
When students develop a strategy they can apply to a variety of contexts, their math thinking gets validation and purpose.  

So whether you lean into a more structured approach or prefer to let kids figure the LEGOS out themselves, small mindset changes like these can create more space for your students to discover, describe, and develop as mathematicians.

Make math fluency fun 

As with someone fluent in a language, someone fluent in math is able to think and calculate mathematically without struggle or effort—that is, with fluidity. 

In order to think and calculate fluently, students need to build a toolbox of strategies—and games are a great way to do that. 

While you’re making the learning fun, students are absorbing tools they’ll use throughout their lives. “When we ensure that every student has access to a range of strategies, and has regular opportunities to choose among those strategies, that’s what games do for us.” says Bay-Williams.

Elevate student voices 

When student thinking isn’t explicitly invited into the classroom, students may begin to narrow their focus, providing merely what they think their teacher wants to hear. But given genuine invitations to share, students are more likely to follow their thought process wherever it leads them, taking a more organic approach to problem-solving.

“Taking a step back as a teacher, and inviting students to take a step forward, [activates] students getting started with finding the answer,” says Stephanie Blair, vice president of Desmos Coaching. “And all of them might take a different step forward, which is okay.”

It’s time for math that does more for students

“All students need the opportunity to feel like they can figure out mathematics,” says Bay-Williams. We need to connect with our students, nurture their curiosity and comfort with math, and welcome their unique ways of thinking.

We hope the thought leaders and speakers from our Math Symposium have inspired you to do just that!

Science of Reading principles that guide early literacy

Our understanding of the natural world is grounded in basic truths or laws we call scientific principles.

And we’ve got a similar set of principles for the Science of Reading.

In science, we have things like gravity, buoyancy, and the laws of motion, while the Science of Reading has universality, vocabulary, background knowledge, and so much more.

These principles, which are grounded in extensive Science of Reading research, inform our understanding of how children learn to read and guide educators in implementing best practices for science-based, effective literacy instruction.

These principles can support you in bringing the Science of Reading into your classroom and fostering literacy success for all your students.

Let’s take a look.

Science of Reading principles

We’ve identified 10 principles that touch on key Science of Reading components. Here’s a peek at the first five.

1. Science-based reading instruction supports all children.

Every child deserves access to high-quality instruction that can help them become proficient readers. The latest National Assessment of Educational Progress (NAEP) data shows that students’ reading scores are slipping, with 37% of fourth graders performing below the NAEP Basic level in reading in 2022. Fortunately, we have the research and tools we need to get to work reversing this trend—and more and more educators are using them. Science-based reading instruction channels decades of research into teaching methods that match the diverse needs of all students. Using the Science of Reading, we can raise those scores and support literacy development for this generation and the next.

2. Reading and writing must be taught systematically, explicitly, and cumulatively.

Humans typically learn to speak naturally, through social interaction. But reading and writing require formal instruction. According to the Simple View of Reading, reading comprehension is the product of both decoding and linguistic comprehension. Kids must be taught the relationships between sounds and letters (phonemic awareness and phonics), and how to decode words. Systematic instruction presents these skills in a logical order, explicit instruction goes beyond just “exposing” kids to words and texts, and cumulative instruction builds on skills learned before. This structured approach is essential for laying a strong foundation in literacy.

3. Proficient reading requires word recognition and language comprehension, while proficient writing requires transcription and composition skills.

Proficient readers recognize words quickly and effortlessly, allowing them to focus on understanding the text rather than decoding each word. They are then able to comprehend language using a knowledge of vocabulary, an understanding of sentence structure, and the skill of meaning-making. Likewise, proficient writers possess transcription skills, including spelling and handwriting. And as in reading, these transcription skills eventually become automatic, allowing students to expend less effort on handwriting, typing, and spelling and redirect that energy toward creating text and sharing ideas.

4. Reading and writing are mutually reinforcing processes that should be taught through integrated instruction.

When students read a variety of texts, they absorb different writing styles, structures, and vocabularies, which also serve as models for their own writing. Writing about what they read also helps students deepen their capacity for both comprehension and expression. Integrated instruction might include activities like reading a historical novel and writing diary entries from the perspective of a character, or researching a scientific topic and creating an informative brochure.

5. Background knowledge and vocabulary are critical to both reading comprehension and writing composition.

Background knowledge is like Velcro to which new texts, and new knowledge itself, can stick. A robust vocabulary is crucial for reading comprehension, because it allows students to understand and engage with more complex material. In writing, a rich vocabulary lets students express their ideas more precisely and vividly. Integrated activities such as book clubs or writing workshops can build background knowledge, vocabulary, and the natural interplay between reading and writing, fostering a holistic—and science-backed—approach to literacy development.

You’re part of a larger community—one made up of educators and researchers invested in deepening our understanding of how kids learn to read and write, and how to bring those approaches into the classroom. Start every day inspired and grounded in this community with our Science of Reading principles placemat.

S3-05: Thinking is power

A graphic with the text "Science Connections" and "Amplify" features colorful circles and curved lines on a dark gray background.

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!

DOWNLOAD TRANSCRIPT

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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What Melanie Trecek-King says about science

“Students carry in their pocket access to basically all of humanity’s knowledge at this moment in time. The question is: do they know what they’re looking for?”

– Melanie Trecek-King

Associate Professor of Biology at Massasoit Community College and creator of Thinking is Power

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.

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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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Free resources: Science and literacy poster pack

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Welcome to Grade 3

BACK TO MAIN TK–5 PAGE

Amplify Science California is so effective you can cover 100% of the NGSS in half the time of other programs.

You can breathe a sigh of relief knowing all you need is:

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What students learn

Lauren Learner loves science. Watch this video to find out what she learns in third grade. >

When you’re ready:

  • Find a summary of each unit below including each unit’s student role and anchor phenomenon.
  • Click on the orange “See how the unit works” link to download a helpful Unit Guide. These guides make great companions to busy reviewers looking for a big-picture understanding of how each unit works.
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Unit 1

Balancing Forces


Student role: Engineers

Phenomenon: The fictional town of Faraday is getting a new train. Unlike typical trains, this one floats, which is causing some concern among the town’s citizens.

See how this unit works

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Unit 2

Inheritance and Traits


Student role: Wildlife biologists

Phenomenon: An adopted wolf in Graystone National Park has some traits in common with one wolf pack in the park and other traits in common with a different pack.

See how this unit works

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Unit 3

Environments and Survival

Student role: Biomimicry engineers

Phenomenon: Over 10 years, a population of grove snails has changed. Populations with yellow shells have decreased, while those with banded shells have increased.

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Unit 4

Weather and Climate


Student role: Meteorologists

Phenomenon: Three different islands, each a contender for becoming an orangutan reserve, experience different weather patterns.

See how this unit works

How teachers teach

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When you’re ready:

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  • Click on the orange links below each component to see grade-specific samples.
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Classroom Slides

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.

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Sample Classroom Slides

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[Grade 3] Balancing Forces

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Plant and Animal Relationships

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Materials Kits

Our kits include enough non-consumable materials to support a class of 36 students and enough consumable items to support 72 students. In other words, each kit can last two years! Plus, our unit-specific kits mean you just grab the tub you need and then put it all back with ease.

Two science textbooks titled "Postales de accidentes geográficos" and "Landform Postcards," both featuring landscapes and natural elements on their covers.
Student Books

Our award-winning Student Books include content-rich nonfiction and informational texts designed to introduce concepts and also deepen understanding. Books are read to, with, and by students with ample scaffolding and support provided by the teacher in whole-class, small-groups, and student pairs.

A diagram shows labeled forces acting on an object, with arrows indicating directions and a key for object, force, and force-type labels at the bottom.
Practice Tools

Our digital Practice Tools feature easy-to-use drag-and-drop and data-entry activities that support the practice of important SEPs like sorting, modeling, or visualizing information. Practice Tools can be used as a whole group, in small groups, or with a partner.

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Consumable Notebooks

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.

A man wearing glasses and a maroon shirt smiles at the camera on a laptop screen with the words "MYSTERY doug" and a speech bubble saying "Doug.
Mystery Science

Our exclusive partnership with Mystery Science means you get our NGSS core curriculum plus two years of free access to Mystery Doug and his extensive library of captivating videos that deepen students’ understanding of each unit’s phenomenon.

Mystery Science lesson alignment

A person with headphones works on a laptop; a line from their head transforms into a rocket, symbolizing imagination, innovation, and the foundational skills essential for multilingual learners.

Coming Soon

Unlike other publishers, we don’t make you wait until your next adoption to get the latest and greatest from Amplify. We’re always launching new and exciting features. What’s more, we’ll push them out to you even after you adopt us!

See what’s coming for 2020-2021

Navigating the program

Watch this video showing you how to navigate our digital platform. Then following the instructions below. >

  • Click the orange button below to access the platform.
  • Choose the resources you’d like to review.
  • Pick your grade level from the drop-down menu.
  • Scroll down to find additional grade-level resources.
Access the digital platform now
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[Grade 2] Plant and Animal Relation…

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S3 – 04. Ideas to build math fluency with Valerie Henry, Graham Fletcher, and Tracy Zager

Promotional image for "Math Teacher Lounge" Season 3, Episode 4 titled "Ideas to Build Math Fluency," featuring Valerie Henry, Tracy J. Zager, and Graham Fletcher.

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

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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.

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.

What Valerie Henry says about math

“A lot of very fluent adults don’t always have every fact memorized. ”

– Val Henry

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.

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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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S4 – 01. Joyful math teaching with Kanchan Kant

Podcast cover for "Math Teacher Lounge," Season 4, Episode 1, titled "Joyful math teaching," featuring Kanchan Kant, described as a math educator and transformative leader.

This season on the Math Teacher Lounge podcast, we follow the theme “joyful math” and uncover its meaning.

In this episode, Kanchan Kant joins Bethany Lockhart Johnson and Dan Meyer to discuss the key, early investment she makes at the start of the school year to ensure her math teaching will be joyful for herself and for her students for the rest of the year.

Explore more from Math Teacher Lounge by visiting our main page.

Download Transcript

Dan Meyer (00:00):
Okay, we are recording. Hey folks. Welcome back to Math Teacher Lounge. (laugh)

Bethany Lockhart Johnson (00:06):
Hardly off to a rocking start.

Dan Meyer (00:06):
Yeah. Yeah. <laugh> Did you like my energy there? Hey folks. Welcome back to Math Teacher Lounge. It’s a new season with your host Dan Meyer. And…

Bethany Lockhart Johnson (00:15):
I’m Bethany, Lockhart Johnson. How’s your summer Dan?

Dan Meyer (00:22):
Summer for me feels really hectic as we prepare, here at Amplify, for the new school year, and everyone’s starting these new math programs. So I’ve been feeling quite amped up, like usual in the summer. But also, my kids started big kid school. So I’ve been seeing the educational system from the role of a parent and all the anxieties and I worry, will I be my kids’ teacher’s most annoying parent <laugh> … So what kind of math curriculum you using? Oh, have you heard of core counting? Can I lead a math center? What’s this worksheet about? I’m really worried my kids are just overall gonna hate my vibe when I come around their classes. Uh, <laugh> so lots going on with me.

Bethany Lockhart Johnson (01:06):
It’s already happening for me and I have a toddler.

Dan Meyer (01:10):
<laugh> There we go. Anyway, that’s what I’m up to. That’s how I’m feeling. I’m curious how you’re doing. We haven’t chatted in a while. We’re excited about the podcast, but it’s been a bit, you know? Bethany got a break from me and my antics over the summer. So, how are we finding you here, as we ramp up to the new season?

Bethany Lockhart Johnson (01:24):
Uhhhh. Well, let me just tell you, I have a toddler. That’s kind of all I need to say. Except that’s not all I will say. Of course, I’ll say more. I am exploring, I’m dipping my toe into the extracurricular toddler activities; the music classes of the toddler world, the creative movement of the toddler world. And yeah, I have lots of opinions and lots of things to say about the teachers. And I’m like, Ugh, I can’t wait to be room mom. And just like…<laugh>

Dan Meyer (01:55):
Just let it rip, you know?

Bethany Lockhart Johnson (01:57):
I have opinions on everything and just hope I don’t get kicked out of the class.

Bethany Lockhart Johnson (02:05):
It’s been an eventfully recharging summer and we are ready for this new season. And in fact, we’re so ready that we decided that we were gonna mix up this season. Just a, just a tiny bit. Shall I explain Dan?

Dan Meyer (02:21):
Yeah. Let’s do it.

Bethany Lockhart Johnson (02:22):
So we have loved all the different topics that we have explored in the Math Teacher Lounge world, but we kind of feel like we need to do some more deep dives. So for this season and the foreseeable seasons …

Dan Meyer (02:38):
We’ll see how it goes.

Bethany Lockhart Johnson (02:38):
Let’s stick with this season. For this season. We’re going to be exploring a singular theme.

Dan Meyer (02:46):
We’re not bouncing around. Yep. We’re not bouncing around from a guest to guest going on whatever shiny thing in the river bed catches our eye. We’re gonna take one theme and see where it goes. What we working with here this season?

Bethany Lockhart Johnson (02:57):
This season, we are going to be exploring the idea of joyful math, joyful math. And Dan, the question I have for you is, is the term joyful math one that you use on the regular?

Dan Meyer (03:10):
No, it definitely is not. I think that joy and math are very rarely, you know, connected in the popular mind. Number one, and number two, you know, I’m kind of an ornery fellow, so that’s not my natural kind of description of math. But we decided that it feels like an important one at the moment, because a lot of math teaching–a lot of teaching in general, math teaching in particular–math teaching is often not a joyful discipline for students, where, you know, I’ve done some research where you look at what people type into Google. And I looked at like, what they…why am I bad at X? And I looked at that for where X is math, where it’s science, where it’s reading, where it’s history. And it was just wild to see how many more hits there are out there on the Internet for “why am I bad at math?” People don’t really associate math with joy, but also we’re looking at joyful math in terms of joyful math teaching. Math teaching, teaching in general, is a tough field at the moment with a lot of teachers leaving teaching. And those who remain are having a lot of soul searching and thinking about, why am I here and how do I sustain this work? And in an environment that seems hostile to my interests or my talents, or work-life balance. And so that’ll be the theme that we’re gonna kind of uncover over the course of our season, talking to various interesting guests, including one today about, yeah, joyful math teaching and joyful math.

Dan Meyer (04:43):
And to help us think about what joyful math teaching looks like, we figured we’d first look at what UN-joyful math teaching looks like. It happens to be the case that we’ve been in a pandemic as you might be aware, and teaching has been challenging. And the NEA, our National Education Association, surveyed its member teachers and asked them the following question … Gave a list of issues that school employees have experienced and asked, for each one indicate how serious of a problem this is for you. This is a survey where more than half of members said they are more likely to leave or retire sooner than planned because of the pandemic. And this is almost double the numbers from July, 2020. It’s really hard to keep track of teacher departures and unfilled vacancies across states. So I don’t wanna like blow this up out of proportion, but it does indicate some real challenges in teaching. So Bethany, I was curious, what do you think like at the top of the list, like what kinds of factors, issues facing educators would you imagine there are?

Bethany Lockhart Johnson (05:48):
So if I’m to understand you correctly, these are reasons someone is not actively experiencing joy in the profession of teaching. Like why would they leave?

Dan Meyer (05:58):
Exactly.

Bethany Lockhart Johnson (05:59):
Well, the number one thing that came to mind for me, well, okay. Wait, wait, one other caveat I need to ask about, you said specifically pandemic-related or just in general, because if it’s pandemic-related, then I think, well, there’s health issues, right? That people are concerned about, but in general, the thing that came to mind was a lack of support from administration districts, lack of funding, and overcrowding in classrooms. Like, you know, I saw somebody had 40 students in their classroom. So those are the two things that I can imagine like top on someone’s list that would make them experience less than a joyful day.

Dan Meyer (06:44):
Yeah. There’s a bunch of you’re kind of identifying here. So number seven on the list is lack of respect from parents and the public, which is like 76% of teachers call that out as serious for them. Others that you kind of circled around in terms of resources go like, not enough planning or unstructured time in the job kind of ties into resources. Yeah. But there’s others that are on the list that I’m curious, you wanna take on the swing at it, given what I’ve said here,

Bethany Lockhart Johnson (07:15):
I feel like too much being asked of them, like being asked to wear too many hats, like they’re being asked to not only teach their class, but also cover all the vacancies and supervise recess and, you know, make a delicious, nutritious lunch. That’s what came to mind. Am am I close?

Dan Meyer (07:33):
Yeah. Number four on the list, unfilled job openings leading to more work for remaining staff. People covering, you know, not just the kind of external to teaching work like you’re describing, but also just taking on like losing your prep period, to take on a class that has been unfilled for all kinds of reasons. Yeah.

Bethany Lockhart Johnson (07:54):
Yeah. I’ve only gotten the fourth. Give me one clue, one clue about …

Dan Meyer (07:59):
So, I mean like, so number one is general stress from the coronavirus pandemic, you know, which I feel like …

Bethany Lockhart Johnson (08:06):
I mentioned that.

Dan Meyer (08:07):
I’ll give you that one. Yep, yep, sure. And then number two, close behind, is feeling burned out, which I think ties into what you’re describing as well. I’m giving Bethany credit on that one. The third one is very different from the ones you’ve been describing. I think I cannot in good faith give you even partial credit for this one. I’ll just say it. Student…

Bethany Lockhart Johnson (08:28):
Wait! Dan, this is not how you give clues.

Dan Meyer (08:31):
Here’s a clue. It’s student absences due to COVID19. It’s really hard to deal student absences. That’s your clue.

Bethany Lockhart Johnson (08:40):
That wasn’t a clue that you told me.

Dan Meyer (08:43):
Yeah, let’s see. I think that’s largely it. There’s also pay is too low, is on the list; student behavioral issues, on the list. And I think that about covers it. So all of that, that basket of items has led to more than half of teachers in this survey, saying that they’re more likely to leave or retire from education sooner than planned. And I don’t know. I think we all know teachers who have bailed.

Bethany Lockhart Johnson (09:08):
I’ve never played a board game with you, Dan, but if we ever play a board game, we’re gonna work on your clue giving, ’cause I want to keep guessing. And you just told me.

Dan Meyer (09:22):
Yeah. Yeah.

Bethany Lockhart Johnson (09:22):
In all seriousness, the <laugh>. In all seriousness, I think yes, the stress of the pandemic and students being absent, what some folks are calling unfinished learning, all of those pieces do play into it. But a lot of those things that you’re mentioning on the list are things that are not unique to the pandemic, right? Like those are things that I feel like there is some modicum of control that we could have over shifting the way the culture of the teaching profession is going so that we could create a more joyful experience for educators, administrators, and students.

Dan Meyer (10:03):
Yeah. Good call out. That’s exactly right. We could tax the people who are not in the classrooms more and increase the pay to classroom teachers. You know, there we go.

Bethany Lockhart Johnson (10:11):
Oh. Bingo. Why didn’t we ask you sooner Dan, for your wisdom.

Dan Meyer (10:15):
Yeah. I’m … solved by Dan. Yeah, good point though. So I read that and yeah, I think that there’s been some … people have critiqued the NEA for being very alarmist about teacher departures as the year has ramped up. It has not been quite the flood of departing teachers as was predicted and thank heavens for that, but we should still be very bummed if teachers are unhappy and wanting to leave and feel like they can’t leave. That is definitely not good. So we were really excited to bring to the table, someone who is just a very joyful teacher and one in a very intentional way. Someone who has a lot of discipline in how she approaches the job and the students in it and tries to create a joyful environment for herself, Kanchan Kant. Kanchan is a math and computer science teacher at Newton North High School in Newton, Massachusetts. She’s been sharing her love for math with her students for the past four years, while also being instrumental in setting the culture and ethos of the math department at her school in her role as the assistant department head. We welcome you on the show Kanchan to help us understand joy and math teaching. Thanks for being here.

Bethany Lockhart Johnson (11:29):
Welcome!

Kanchan Kant (11:30):
Thank you for having me. I really appreciate it.

Bethany Lockhart Johnson (11:33):
One of my friends, her son was asked as his first math homework assignment to write out his math bio. And I loved that idea because we got to hear a little bit about your bio from like a broader perspective. But if we were to ask about your math bio, I will speak for myself to say like, automatically certain images flash into my mind, right? To think about my relationship, my evolving relationship with math. But I’m so curious if I was to ask you, what’s your math bio? How did you become the person, mathematically speaking, that you are today? Would you mind sharing a bit about that?

Kanchan Kant (12:10):
Of course I would love to. So I was born and raised in India and I belong to a family which considers mathematics to be extremely important to succeed in life. My father used to have me add and subtract license plates since I was four years old, when we were out and about. I loved math in school, it just made like complete sense to me. It was logical and you know, it was my favorite subject. I loved it all through high school. I had a confidence speed breaker in undergrad. When in my second semester I almost failed the engineering math course that I took. That was the first time math felt like too much and not like my best friend, which it was supposed to be. So it was a while before I could summon the courage to take on another math course in college.

Kanchan Kant (12:56):
But once I did that, it was like old times. I realized I had to persevere through the challenging bits. And once I did that, it started to make sense again. And through my journey, as an educator speaking to people from various backgrounds and like coming to the United States, I realized that math is challenging for everyone at one time or another. For some people that is elementary school. And for some others, it is college or even later. Either way does not mean that you are not a math person. When I was in college, I felt I was not a math person. Whereas my sister, my very own sister said the same thing about math in middle school. Both of us use math every day. And we are definitely, definitely math people. So for me to be a math person is to persevere, to approach problem-solving in a logical manner, and to find the joy in the process ,as well as the answer.

Dan Meyer (13:47):
That’s wonderful. Yeah. A lot of people, have a moment where they feel like almost betrayed by what they thought was a close friend of theirs, with math, where it’s like, wait, I thought we were tight. You know, I thought we were cool. You and me. And there’s that moment. And I wonder if that’s been a useful moment for you to, you know, bring back now and then as a teacher with students who might feel that even, you know, in high school or in a secondary school as a kid.

Kanchan Kant (14:15):
Absolutely. Like when I talk to students and tell them, yes, I had difficulty in math too. It has not always been easy for men and there are still things I struggle with sometimes, then it’s like more modeling for them that you have to persevere, you should persevere. And once you do that, it makes sense and you can feel successful. So, almost every year I end up sharing the story with my students.

Bethany Lockhart Johnson (14:38):
There’s so much value in that, right? That you are sharing that vulnerability with students. And to say your relationship with mathematics has not been, you know, smooth sailing the whole way through. There were times when you had to work harder than others.

Dan Meyer (14:55):
Yeah. Really fun to hear about you and your father as well. I tried to ask my five-year-old to do some skip counting the other day, like, okay, cool, you’re hot stuff. You can count, you know, up by ones, but what about by twos? And the moment really fell flat. And I watched myself becoming the kind of parent who is whose enthusiasm for math is one day resented by his children. I feel a lot of, yeah, I felt your anxiety Kanchan, with math itself. And now I feel anxiety as like someone who loves math and loves to teach math and may one day alienate the people closest to him. <laugh>

Kanchan Kant (15:31):
I don’t like that future. I have a three-month-old. I do not like this future of mine. If I have to go through what you’re going through. Uh, oh, <laugh>

Dan Meyer (15:38):
You got this. So Kanchan, you’re going back to the classroom coming up here at the time of this recording. It’s a few weeks out. And we’re thinking about like the kind of ways that math teachers sustain a disposition that is joyful. How are you feeling right now, as far as going back to class after this summer? Are you feeling excited, anxious, some combo, tell us about it.

Kanchan Kant (16:01):
I would say combo, but more excited than anxious. I was on maternity leave, as I mentioned, before the school year ended, and I missed the students dearly. Like, my students are what gives me hope in the darkest times. They are thoughtful. They’re empathetic. They’re so eager to learn. And very soon into my teaching career, I realized that if I take the time to get to know my students and make them feel safe and seen in my class, teaching them math would be so much easier and so much more fun. So I’m a little worried about this being like fourth year into the pandemic, but let’s see. Last year I felt the students were finding it difficult to interact with and work with their classmates because they had not been doing it for so long. So I’m hoping this year would go a little better and I’m really looking forward to working with them and building community and see how it goes.

Dan Meyer (16:53):
So if I’m understanding you correctly, you are feeling very well recharged here. You had basically an extended summer with this maternity leave, basically just like a lot of rest and relaxation over the last, like several months. Um, if I get you here. So anyway, I’m glad for that for you. And, yeah. I also hear you on the difficulties of teaching post pandemic or mid pandemic. Anyway, thanks for sharing that.

Bethany Lockhart Johnson (17:19):
What I love is I hear you being so intentional, like thinking about those relationships and thinking about that community that you want to build, you know? How do you hope that you’re gonna cultivate joy in your teaching this year? I mean like, are there certain routines or disciplines that you specifically call forth or that you think other teachers should think about?

Kanchan Kant (17:41):
So at the start of every school year, I dedicate like about three to four weeks to set up the classroom culture, both social and academic. I call my classroom a learning community. We start with community circles, we do icebreaker activities, group building and all those kinds of things. But most importantly, we do a lot of collective problem solving. So I try to present students with problems, which can be solved using multiple strategies and have multiple entry points, basically they are low floor, high ceiling problems. These could be stretch problems that they have seen before, like concepts that they already know or logical puzzles, or just wrapping their heads around different problems. Then I have students share their strategies. The more strategies they have on the board, the more successful I think the problem was. Every year, inevitably, students come up with strategies that I’ve never ever seen before for the same problems that I do.

Kanchan Kant (18:35):
And so I have students come up to the board, they would share their strategies. If they’re not ready for that, they would walk me through their strategies. And I would write their name on the board with different colored markers and everything. Basically to give them choice and agency. It also shows them that the process of doing the problem is so much more important than just getting the right answer and that it is okay to make mistakes in our learning community. I use a lot of vertical whiteboards, some concepts and problems align so well with the vertical surfaces, especially when students can explore together, learn from each other. So I do a lot of that. As for routines, I would say consistency is the key. I consistently reinforce that I want to hear multiple strategies, that it is okay to make mistakes. I am willing to learn from you as much as you’re willing to learn from me. So all like that consistency in culture more than the routines, is I feel important to bring that joy.

Dan Meyer (19:29):
That’s super interesting. Thanks for that. So I’ve heard, I hear two common objections or two common concerns to using rich tasks or doing problem solving. And I think I heard like answers to those two common reservations within what you described there, but I wonder if we can kind of bring it to the surface. And so one of the reservations is around the time that those problems take and another is that teachers often feel like, well, I might be surprised, you know, I might not know what to do with what a student does. And I thought I was hearing like some very interesting answers to both of those kinds of reservations from you, but would you just surface those up if you have some.

Kanchan Kant (20:09):
So in terms of time, I feel if I spend the time at the beginning of the year, setting up that community and doing those problems, it makes learning the math and learning the concepts much more faster throughout the rest of the year. And even when I am trying, like, even throughout the year, if we are doing a warm up problem, as I call it, which has multiple strategies, that’s gonna clarify so many more concepts when we talk about those five, 10 strategies of doing the same problem, then going through multiple problems to clarify those concepts. So for me, it actually saves time instead of taking more time.

Dan Meyer (20:43):
Hmm. That’s super interesting. It’s an investment I’m hearing from you that, yeah, you might not be hitting the curriculum quite as hard early on, but that all of a sudden you’re in the spring and it’s like, oh wow, we’ve been moving so much faster through territory that has been more challenging. What would you say to you know, comfort concerned educators or to address the concern that I don’t know what I’ll do with these five, 10 different strategies. You say, I always see strategies that I’ve never anticipated. Like, it’s a good thing, you know, like you’re happy about that. I think that’s a very intimidating thing for lots of educators. What would you say to that?

Kanchan Kant (21:19):
I think like, for me, it’s a good kind of discomfort. That means like a student is teaching me something, which is actually doing two things. One modeling for them that I’m willing to learn and that I don’t know everything. And two, also telling them that they’re mathematicians. They know what they’re doing. They’re not just receivers of math, they’re actually creating it. So for me, that is very, very important.

Bethany Lockhart Johnson (21:43):
I love that so much. When you think about your students and you’re about to start this new school year, how do you hope your students will experience math in your classroom?

Kanchan Kant (21:53):
So I hope my students can see the beauty and joy of math. They can see that math is a way to see the world and not as something we have to do to get through school. So my hope for my classroom is that we can learn to problem-solve and persevere through problems and learn from each other and not just get through the curriculum. Because like, I think math is a wonderful way to learn these skills, which are so important when you get out of high school. Most importantly, I just wanna make sure that my students see themselves as mathematicians. And like one of the things that like I have to share with you that, because one of my highlights for the year has to be the Desmos art project. I do it every year for the past three years, I think since I’ve started teaching sophomores. And I do it as a unit assessment for functions and my students design something that is meaningful to them, using all the different kinds of functions and colors and shading and everything that you can think of in Desmos.

Kanchan Kant (22:49):
Thank you so much for that though. It is such a cool way for me to see them do that. Like I have seen such amazing creations. One of my students once made a scaled working model of a solar system wherein the planets were rotating at relative speed. The Saturn had rings and they were like asteroids and everything. And then it was beautifully done. Then there was another one who did a very, very detailed whale scenery, her reasoning. I wanna be a Marine biologist and I wanna study whales. So this is what is meaningful to me. So like that one project is just a culmination of everything that I want students to see in math and in my classroom. And like I do more of those kinds of things, but that is one thing that it’s one of the highlights of my year.

Dan Meyer (23:32):
That’s awesome. I love hearing that. Yeah. Shout out to the team at Desmos Studio for building and continuing to develop a tool list that so good for art and animation, even, in addition to some mathematics with a more computational kind. Yeah, that’s really exciting. What’s interesting to me is that you teach high school, and I think that like students at that age have a very well-defined sense of what math is and who they are as mathematicians. And then along you come, you know, and like offer this really interesting disruption, you know, in their sophomore year of high school that like, oh, this can be totally different, this relationship who I am. And that’s just really exciting. I imagine it’s a very surprising year. I would imagine that first month, I would imagine is a very surprising month for a lot of your sophomores.

Kanchan Kant (24:20):
Yeah, it is. I mean, that’s why I take that time to build that community because then that sets the tone and the relationship that we’re gonna have for the rest of the year. Students get to know how to work with each other. They get to know each other, that whole piece is like super important because of that.

Dan Meyer (24:35):
Yeah. That’s awesome. So here’s the thing, like we’re exploring these ideas about joyful math teaching and what it will take to cultivate restore, reclaim joy in math, teaching this next year. And you’ve offered us these really interesting ideas some, some very, you know, philosophical and some technical about how you spend time in ways that lead to joy in the spring for you and your students. Love that. We don’t want to as hosts, as researchers, investigators of this joyful math teaching idea, we don’t wanna say it’s all up to teachers to change their mindset, to do different technical practices, and that will lead to joy. We also wanna be really attentive to the environment that surrounds you, the people who are around to support you, the policy makers, the social structures that influence your joy in very significant ways. So what we would love to know from you is, how are you supported by the greater educational community in keeping your joy in your work? I’m thinking, especially about administrators, you know, front office, staff, parents, even, can you name a few ways for those sorts of people who listen to this podcast, how they can cultivate a math teacher’s joy this coming year?

Kanchan Kant (25:54):
I would say trust. I think more than anything, educators want administrators, parents, the greater educational community, to trust them to be professionals and experts in what they do. That does not mean that we don’t want to learn, that we don’t want feedback, that we don’t wanna get better. It just means that we keep the wellbeing of our students as our top priority. And we would like to be trusted to do just that. Also just keeping in mind that whether we like it or not, we are still adjusting to the new normal while recovering from the worst of the pandemic times. A lot of us are recovering from trauma, a lot of our students are recovering from trauma, and we need time and space for our social and emotional wellbeing.

Dan Meyer (26:35):
Yeah. I’m really curious, Kanchan, you’ve done a lot of work in your area with your grading team and in thinking about equitable and biased resistant instruction. I’m curious how you see those efforts lining up with creating joyful math learning conditions for all students, not just students from a dominant culture of math doing, let’s say.

Kanchan Kant (26:55):
For me, creating an equitable environment in a classroom is most important because once you have that, that’s when you have the relationships, that’s when you have the culture, that’s when all students actually thrive. So to that end, our school and our department has been doing a lot of work around grading practices. We actually assess how we grade students, where the bias is, what we can do to make them more bias resistant. Should we move to mastery based grading? Like that’s something I’ve been experimenting with for the past two years. Through the pandemic, I started doing mastery based grading so that my students can get more opportunities to show that they have learned the content. And so like just little things which help bridge the opportunity gap. I would say another project that our school undertakes is called the calculus project wherein we have students in Black, Latinx, and low income families sign up for that and are recommended for that. And then we do summer classes and yearlong support to preview the material for next year, not as a remedial class, but to actually set students up for success in AP classes for the coming year. So we have the community buildup. We have the courses we have like math support. It’s a very beautiful thing actually. And I’ve been working with that program for four years now. So yeah, so those are my ways of creating more equity in our school.

Bethany Lockhart Johnson (28:19):
That’s so beautiful and I deeply, deeply wish you had been my high school math teacher. And I have to say that the theme that I kind of keep hearing is this intentionality. How you are so intentional about your work, not just with what your students are learning, but how they’re learning it, how they are engaging with this subject and how they are building their own relationship. You talked a little bit about your relationship over the years with mathematics, but how are your students building that relationship? And so I’m just very appreciative of you sharing that with us and with our listeners. And we are so excited to have learned a little bit about, like, I feel like I got a little mini peek into your classroom.

Kanchan Kant (29:03):
Thank you.

Bethany Lockhart Johnson (29:04):
And can I say that if you are listening to this prior to October at NCTM Los Angeles, you will get to hear Kanchan Kant speak at Shadow Con. Can I give that away, Dan? Is that, is that …

Dan Meyer (29:23):
You can drop that. Yeah, It’s pretty top secret.

Bethany Lockhart Johnson (29:26):
Can I drop it?

Dan Meyer (29:27):
Yeah. Do it. Yeah.

Bethany Lockhart Johnson (29:28):
Dan and I will be in the audience cheering you on. It’s been a joy to learn with and from you, and we are so excited to just, you know, kind of keep marinating on some of these ideas about how we can continue to be intentional about creating joyful math spaces for our students. Thank you so much for joining us today.
Kanchan Kant (29:49):
Thank you so much. It was a real pleasure.

Dan Meyer (29:57):
So Bethany, I loved hearing Kanchan talk about both her, just her joyful personality, but how she cultivates joy through craft and technique through, you know, through the various ways she interacts with students in intentional ways, that those make the job more joyful for her. And I thought it was really interesting to hear her talk about how autonomy is the thing that she needs most in her job environment to feel like she can be joyful in her work. In that context, I saw … something on Twitter popped up for me in my, you know, my many Twitter wanderings. This is a segment we might call, Dan finds something on Twitter and shares it with Bethany. Which we’ll tighten that up a little bit, but I’m sending this over to you right now, and I’d love to know as you check this out, what you’re seeing and what you’re thinking and we’ll chat about how it relates to our interview here in a moment.

Bethany Lockhart Johnson (30:47):
All right. I’m ready, send it over. It’s opening. So this appears to be a document by the way, outlining, maybe it’s a district, maybe it’s administration, they’re outlining expectation type and expectation guidelines. Hmm. Okay. And these are lesson plan expectations. Expectation type. Timeliness. Plans are due no later than 6 p.m.. Friday prior to the week of instruction. Comprehensive, all activities for the week for all subjects taught should be included and complete by due date and time. Plans should have at minimum, the following, see template for detail. Okay. So then it goes through the things that the plans need to have, the topic title, target, the objective, the activities, the sequence, the display agendas to be displayed backward design. Okay. So basically <laugh>, we were just talking about, overwhelm. And when I see this document, listeners, have you ever received something from your administrator or anyone, let’s take it more broadly, that is requesting something of you that would take so much time to complete and be so out of touch with your lived reality that it really genuinely sucks the joy out of the experience.

Bethany Lockhart Johnson (32:25):
So the first thing that I see that this document, and again, the goal of whichever district’s plan this is, is that these expectations will lead–now, mind you, I am a fan of like, you know, looking ahead, I’m not a like, oh, hey, what am I gonna teach in five minutes? No, but the idea that then it lays out all of the things in such detail that you’re gonna be teaching feels like one of those pacing guides where, oh, move on to the next page, whether or not your students have any sort of sense making whatsoever. So my first thought is, oh, sad. I have to stay here. I’ll be there past 6 p.m. But I’m gonna be there trying to make the plans for the next week based on what I think my students have learned. Hmm it’s sounds like a little bit of a bummer. Dan, what did you think when you saw this and did I do a fair description of what it is?

Dan Meyer (33:25):
No, it’s, it’s a tough one to describe, ’cause it’s basically a wall of text and commands from an administrator who like, I just have to imagine has just like acres and acres of teachers trying to beat down their door to teach at this school, if this is how you’re gonna treat your teachers. I mean just, yeah. The idea of having a week… I’m with you, you don’t wanna just like, just jump in by the seat of your pants, but the idea of having a full week of lessons for every section you teach, every prep you teach, planned and submitted with every minute, basically morseled out to different goals. It says down here, you gotta like, for all of these, download a CSV of grades and whatnot and attach those. It’s the sort of thing, like you said, there are some edicts that you get from administration where you just have to laugh or just like, you have definitely missed like what I am willing to do here. It’s so far beyond. Yeah. I can’t imagine it. And it just felt like, yeah, it was a great way to get teachers like Kanchan to feel like a real lack of autonomy. Like it’s this would not work. I don’t think.

Bethany Lockhart Johnson (34:33):
And it’s not even like willing to do. Like, let’s say you’re even willing to produce it. Let’s say that me, the rule follower is like, okay. I’m gonna attempt to meet these demands. One, most teachers were just, you know, they probably would put baloney down there anyway. Not saying that I would, but I’m saying like, it’s clearly just a hoop that they’re having to jump through and two…

Dan Meyer (35:04):
Yeah. Compliance, right?

Bethany Lockhart Johnson (35:05):
Yeah. Compliance, compliance. There you go. And two, yeah, it feels like it’s about control and not trusting the teacher. And I love that. Kanchan said that trust is what she needs. Right? You’re hiring me. Yes. I still have lots to learn, but you’re trusting me and you’re creating an environment where I can continue to learn from and with my students. And if I was being asked to submit this tome every Friday before six, that is predicting, what does it say, anticipating the steps necessary for student mastery? You know, I kind of feel like maybe it’s like that one or two teachers where maybe they feel like, oh, I don’t trust that teacher or that teacher isn’t doing a good job, whatever. We better do this for all of the teachers, but then it’s not gonna change the practices of that one teacher and all the other teachers are gonna be resentful.

Dan Meyer (36:00):
Like if there was like feedback that came back to you on, you know, on lesson plans or there was some like something that was very constructive or productive, like maybe that would be different, but it really just feels like these are gonna go into a digital drawer somewhere and not be looked at, at all.

Bethany Lockhart Johnson (36:15):
Yes. The digital drawer. Like I’m gonna send you this report and then nothing is going to happen with it. Except that four hours of my time. Well, you wouldn’t do it, but <laugh>…

Dan Meyer (36:29):
You’ve worn me down. You’ve worn me down. I’m now putty in your hands and more compliant for the next thing. And I also just wanna shout out the administrator today, who I emailed asking about like a teacher participating in a project and this administrator said, I have a standing policy not to email teachers over summer break, which you know, as administrators out there doing just the good work, you know, trusting teachers, watching out for them, trying to be a force multiplier for teachers, making the road wider, the way easier for teachers. So shout out to y’all doing the out there. Really appreciate that.

Bethany Lockhart Johnson (37:04):
Okay. Wait, wait. About that email thing, quick question. Did you ever check your email over the summer?

Dan Meyer (37:11):
Uh, yeah. That’s one way in which I was the, you know, I just love email, you know? Oh. Someone wanted to reach out. Oh, oh, Banana Republic wants to tell me about new clothes that are on offer. <laugh> I mean like, it’s just, I love those personal emails. So yeah, I did check my email over the summer.

Bethany Lockhart Johnson (37:26):
Somebody emailed me recently and they emailed me at like two in the morning. And because I currently have a toddler, I received the email at four in the morning because you know, the best thing to help myself fall back asleep is to hop on my phone, right? Like I’m already up trying to get my toddler back to sleep. I might as well start scrolling. Anyway, so the person had this little thing at the bottom of their email and it said, I have, something to the effect of, I have really like wonky work hours. I may be sending this outside of the like more standard nine to five. But please don’t feel pressure in any way to respond outside of your time. Would you appreciate that, seeing that or does it make you feel like you should respond? ‘Cause I almost responded at four in the morning, and maybe that says something about …

Dan Meyer (38:15):
They’re telling you not to respond.

Bethany Lockhart Johnson (38:16):
I know it was helpful.

Dan Meyer (38:18):
It says don’t, but you’re like, what if they’re saying that because they really expect me to respond and this is one of many ways that you and I are different. I’m always happy to see that.

Bethany Lockhart Johnson (38:29):
Do you respond? I’ve texted you in the evening because you know I have some wonky hours. Do you respond to things, like where’s your boundary there? Or when you were in the classroom, where was your boundary there? Did parents have your phone number?

Dan Meyer (38:43):
No. I gave kids my cell phone number for a couple years and it was a wobbly experiment. But parents will email, you know, back and forth with you. And I think the best thing to like … I love just like adding some friction, some latency into the kind of the chain, you know, like I hate going like back and forth, like da, da, da, da, and then like respond and then da, da da respond. And it just like goes back and forth. So just like just sitting back for an hour or two hours, you know, not responding, just let someone cool down, calm down. Email just gets you more email. That’s like if you send an email, you are just making it more likely to get more email. It’s a, you know, it’s a problem.

Bethany Lockhart Johnson (39:20):
Are you one of the zero people?

Dan Meyer (39:23):
My inbox is at zero. Most days before work.

Bethany Lockhart Johnson (39:26):
You’re joking!

Dan Meyer (39:28):
I end work every day with inbox, at zero.

Bethany Lockhart Johnson (39:31):
You’re joking!

Dan Meyer (39:32):
That’s just, you know.

Bethany Lockhart Johnson (39:33):
Who are you?

Dan Meyer (39:34):
You know, you should take my life coaching, Bethany. I’ll give you a discount since we’re math teacher, lunch pals. But, um yeah. I can help.

Bethany Lockhart Johnson (39:44):
Thank you for qualifying where our pal-dom lives. I wouldn’t even tell you how many are in my inbox. Point is, if you are actively starting the school year, we celebrate you and we are here and over the next few months, we’re gonna be diving into joyful math and that definition’s gonna keep evolving. But I wanna say something that is making me feel a little joyful, Dan. You ready?

Dan Meyer (40:15):
Tell me.

Bethany Lockhart Johnson (40:16):
You and I, in person, at NCTM, the National Council for Teachers and Mathematics. It’s coming up and we are going to be recording Math Teacher Lounge, live. Live, in person! And I hear there’s gonna be like a t-shirt cannon and there’s gonna be, you know, like musicians marching through the aisles or something.

Dan Meyer (40:46):
A marching band?

Bethany Lockhart Johnson (40:46):
A marching band!

Dan Meyer (40:46):
Trained animals. Yeah.

Bethany Lockhart Johnson (40:48):
But the point is, I’m so excited, Dan. And you know, when I see you, I might just, it’s been so long since I’ve seen you, Dan. I’d love to give you a big old embrace.

Dan Meyer (41:04):
You might just, you might just cry. Yeah. Yeah. It’ll be great. Yeah. It’s gonna be awesome for you folks to see me and Bethany have a real awkward first hug since the pandemic. And, uh, but it’s gonna be a blast to hang with us in person. We’ll have some special guests, probably, some interesting segments. You folks should stop on by at NCTM, if you’re gonna be there. Highly recommended.

Bethany Lockhart Johnson (41:29):
Now, we will be broadcasting that episode. You’re gonna get to hear … we’re gonna record it live. It’s gonna happen. In the meantime, you can find us at MTLshow on Twitter, or you can find us in our Facebook group, Math Teacher Lounge. We can’t wait to hear from you. And we’d love to hear what makes math joyful for you? Where can we add a little bit more joy to you this, this season? So thrilled to be back. Thanks for listening.

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.

What Kanchan Kant says about math

“Creating an equitable environment in the classroom is most important because once you have that, that’s when you have the relationships, and that’s when all students actually thrive.”

– Kanchan Kant

Meet the guest

As a math and computer science teacher at Newton North High School, Newton, MA, Kanchan has been sharing her love for math with her students for the past four years. Kanchan is instrumental in setting the culture and ethos of the mathematics department at her school in her role as the Assistant Department Head. Kanchan also leads the Math Department Grading Team and has been instrumental in making grading policies which are more equitable and bias resistant. In her new role as a Transformative Leaders of Massachusetts Fellow in collaboration with Springpoint and Barr Foundation, Kanchan looks forward to making equity and joy of learning the foundation of many more classrooms.

Businesswoman with long dark hair, wearing a dark blazer and blue blouse, poses in a professional portrait against a light background, representing math programs.
A graphic with the text "Math Teacher Lounge with Bethany Lockhart Johnson and Dan Meyer" on colored overlapping circles.

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 video call screen showing a math problem on the left with a play button overlay, and two participants on the right in individual video boxes. "MATH TEACHER LOUNGE" text is at the bottom.

Free professional development cours…

Three on-demand professional learning courses for math teachers.  Earn your cert…

Mathigon logo featuring colorful geometric shapes on a dark background.

Mathigon: the mathematical playgrou…

Math games and manipulatives for online and remote learning.

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Desmos Classroom Grades 3–12

Join Desmos Classroom to gain access to free classroom lessons, lesson-building…

We are the program for Idaho’s middle school students and teachers.

Amplify ELA is a blended curriculum designed specifically for grades 6–8. With Amplify ELA, students learn to tackle any complex text and make observations, grapple with interesting ideas, and find relevance for themselves.

Built for middle school teachers and students

We are the program for Idaho’s teachers, offering rich texts that are a delight to teach, better connections with your students through powerful differentiation and assessment tools, and step-by-step instructional guides that save you time and simplify your day.

All-green rating on EdReports

The results are in! Amplify ELA earned an all-green rating from the independent review group.

Read the review on EdReports.

Our approach

Amplify ELA lessons follow a structure that is grounded in regular routines but flexible enough to allow for a variety of learning experiences. Each grade includes six units centered on literary or informational texts, delivered in several forms of media. Your classroom will also benefit from two to three immersive learning experiences called Quests and a dedicated Story Writing unit. With our new hybrid design, teachers can make choices about when their students use devices without compromising learning and providing 100% standards coverage.

We empower students to become critical thinkers.

With text always at the center, students are encouraged to make meaning for themselves. They develop ideas and opinions on real-world, relevant texts, instead of focusing on right or wrong answers.

We provide opportunities for all students to work “up.”

Multiple entry points and differentiated supports allow every student, regardless of fluency or ability level, to engage deeply with the same complex texts and rigorous curriculum.

We assess while you instruct.

Formative assessment reports provide a continually updated picture of how each student is progressing with key skills and standards. Each learning moment provides a small piece of data, allowing you to keep teaching while building a clear understanding of student performance.

Download a free white paper

Beyond “make it fun”: Four principles of true engagement in middle school ELA

Download the white paper

What’s included

Rigorous core curriculum that empowers teachers and engages middle school students

Student Edition

Available digitally and in print, the student materials guide middle schoolers through complex texts and writing by:

  • engaging students with high-quality narrative and informational texts
  • providing videos, audio supports, and digital experiences that capture their attention
  • keeping all of their writing in one place with the personal writing journal

Teacher Edition

Available digitally and in print, the Teacher’s Edition contains all of the information teachers need to facilitate classroom instruction, including:

  • detailed lesson plans
  • video teacher tips embedded in the lesson
  • standards alignment and exit tickets
  • real-time differentiation strategies
  • robust reporting

Interactive Quests

Quests are fun, week-long explorations where students practice analytical reading, writing, speaking, and listening skills all while building a strong classroom community.

Digital library for independent reading

Amplify Library: Our expansive digital library includes more than 650 fiction and nonfiction, classic, and contemporary titles.

Amplify ELA makes teachers’ lives easier

We help teachers make sure the standards are covered, the skills are taught, your students are scaffolded and encouraged, and the test is prepped.

  • Embedded differentiation to support all readers
  • Informative and streamlined assessment system
  • Robust reporting that tracks progress
  • Powerful feedback tools
All materials

Explore more programs

Our programs are designed to support and complement one another. Learn more about our related programs.

Amplify Science

Amplify Science is a K–8 science curriculum that blends hands-on investigations,…

See all programs

We are the program for Tennessee’s middle school students and teachers.

Amplify ELA is a blended curriculum designed specifically for grades 6–8. With Amplify ELA, students learn to tackle any complex text and make observations, grapple with interesting ideas, and find relevance for themselves.

Built for middle school teachers and students

We are the program for Tennessee’s teachers, offering rich texts that are a delight to teach, better connections with your students through powerful differentiation and assessment tools, and step-by-step instructional guides that save you time and simplify your day.

Circular logo of EdReports featuring Read the ELA Report Review Year 2020 with a partial bar graph and book symbol in yellow and blue.

All-green rating on EdReports

The results are in! Amplify ELA earned an-all green rating from the independent review group.

Read the review on EdReports.

Our approach

Amplify ELA lessons follow a structure that is grounded in regular routines but flexible enough to allow for a variety of learning experiences. Each grade includes six units centered on literary or informational texts, delivered in several forms of media. Your classroom will also benefit from two to three immersive learning experiences called Quests and a dedicated Story Writing unit. With our new hybrid design, teachers can make choices about when their students use devices without compromising learning and providing 100% standards coverage.

We empower students to become critical thinkers.

With text always at the center, students are encouraged to make meaning for themselves. They develop ideas and opinions on real-world, relevant texts, instead of focusing on right or wrong answers.

A student using a laptop
A student using a laptop

We provide opportunities for all students to work “up.”

Multiple entry points and differentiated supports allow every student, regardless of fluency or ability level, to engage deeply with the same complex texts and rigorous curriculum.

We assess while you instruct.

Formative assessment reports provide a continually updated picture of how each student is progressing with key skills and standards. Each learning moment provides a small piece of data, allowing you to keep teaching while building a clear understanding of student performance.

Amplify K–12 programs - A teacher assisting two students

Download a free white paper

Beyond “make it fun”: Four principles of true engagement in middle school ELA

Download the white paper

What’s included

Rigorous core curriculum that empowers teachers and engages middle school students

Student Edition

Available digitally and in print, the student materials guide middle schoolers through complex texts and writing by:

  • engaging students with high-quality narrative and informational texts
  • providing videos, audio supports, and digital experiences that capture their attention
  • keeping all of their writing in one place with the personal writing journal

Teacher Edition

Available digitally and in print, the Teacher’s Edition contains all of the information teachers need to facilitate classroom instruction, including:

  • detailed lesson plans
  • video teacher tips embedded in the lesson
  • standards alignment and exit tickets
  • real-time differentiation strategies
  • robust reporting

Interactive Quests

Quests are fun, week-long explorations where students practice analytical reading, writing, speaking, and listening skills all while building a strong classroom community.

Digital library for independent reading

Amplify Library: Our expansive digital library includes more than 650 fiction and nonfiction, classic, and contemporary titles.

Amplify ELA's digital library for independent reading

Amplify ELA makes teachers’ lives easier

Our program ensures that standards are covered, skills are taught, and students are prepared with proper scaffolding and encouragement.

  • Embedded differentiation to support all readers.
  • Informative and streamlined assessment system.
  • Robust reporting that tracks progress.
  • Powerful feedback tools.
All materials

Explore more programs

Our programs are designed to support and complement one another. Learn more about our related programs.

Amplify Science program header image

Amplify Science

Amplify Science is a K–8 science curriculum that blends hands-on investigations,…

See all programs

We are the program for Indiana’s middle school students and teachers.

Amplify ELA is a blended curriculum designed specifically for grades 6–8. With Amplify ELA, students learn to tackle any complex text and make observations, grapple with interesting ideas, and find relevance for themselves.

Built for middle school teachers and students

We are the program for Indiana’s teachers, offering rich texts that are a delight to teach, better connections with your students through powerful differentiation and assessment tools, and step-by-step instructional guides that save you time and simplify your day.

All-green rating on EdReports

The results are in! Amplify ELA earned an all-green rating from the independent review group.

Read the review on EdReports.

Our approach

Amplify ELA lessons follow a structure that is grounded in regular routines but flexible enough to allow for a variety of learning experiences. Each grade includes six units centered on literary or informational texts, delivered in several forms of media. Your classroom will also benefit from two to three immersive learning experiences called Quests and a dedicated Story Writing unit. With our new hybrid design, teachers can make choices about when their students use devices without compromising learning and providing 100% standards coverage.

We empower students to become critical thinkers.

With text always at the center, students are encouraged to make meaning for themselves. They develop ideas and opinions on real-world, relevant texts, instead of focusing on right or wrong answers.

We provide opportunities for all students to work “up.”

Multiple entry points and differentiated supports allow every student, regardless of fluency or ability level, to engage deeply with the same complex texts and rigorous curriculum.

We assess while you instruct.

Formative assessment reports provide a continually updated picture of how each student is progressing with key skills and standards. Each learning moment provides a small piece of data, allowing you to keep teaching while building a clear understanding of student performance.

Download a free white paper

Beyond “make it fun”: Four principles of true engagement in middle school ELA

Download the white paper

What’s included

Rigorous core curriculum that empowers teachers and engages middle school students

Student Edition

Available digitally and in print, the student materials guide middle schoolers through complex texts and writing by:

  • Engaging students with high-quality narrative and informational texts.
  • Providing videos, audio supports, and digital experiences that capture their attention.
  • Keeping all of their writing in one place with the personal writing journal

Teacher Edition

Available digitally and in print, the Teacher’s Edition contains all of the information teachers need to facilitate classroom instruction, including:

  • Detailed lesson plans.
  • Video teacher tips embedded in the lesson.
  • Indiana Academic Standards alignment and exit tickets
  • Real-time differentiation strategies.
  • Robust reporting.

Interactive Quests

Quests are fun, week-long explorations where students practice analytical reading, writing, speaking, and listening skills all while building a strong classroom community.

Digital library for independent reading

Amplify Library: Our expansive digital library includes more than 650 fiction and nonfiction, classic, and contemporary titles.

Amplify ELA makes teachers’ lives easier

We help teachers make sure the standards are covered, the skills are taught, your students are scaffolded and encouraged, and the test is prepped.

  • Embedded differentiation to support all readers.
  • Informative and streamlined assessment system.
  • Robust reporting that tracks progress.
  • Powerful feedback tools.
All materials

Explore more programs

Our programs are designed to support and complement one another. Learn more about our related programs.

Amplify Science

Amplify Science is a K–8 science curriculum that blends hands-on investigations,…

See all programs

At Amplify, we believe Pennsylvania students and teachers deserve high quality instructional materials.

That’s why we partner with schools across the Keystone State to meet their core curriculum, assessment, and intervention goals. With solutions grounded in research and evidence-based practices, Amplify is leading the way with rigorous and relevant learning experiences.

Select a program below to learn more.

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Group of diverse middle school students working on laptops and discussing in classroom.

Amplify Desmos Math (K–12)

Amplify Desmos Math is a comprehensive K–12 math suite that has everything in one place: benchmark and progress monitoring, core instruction, integrated personal learning, embedded intervention, and more. This structured, problem-based approach builds on students’ curiosity while strategically developing math fluency and lasting grade-level understanding. The program delivers:

  • Engaging, discourse-rich math lessons that fuel classroom conversations and drive the learning process.
  • Comprehensive integrated resources, including print and digital, along with manipulatives and Centers Kits in K–5.
  • Real-time insights, data, and reporting that inform instruction and celebrate student thinking.

Flexible, social problem-solving experiences

Digital lessons should be able to bring student thinking to the surface and spark productive discussions. We bring this vision to life with interactive social, collaborative lessons powered by Desmos technology.

Start exploring
A teacher using a tablet interacts with a young student in a classroom, with educational posters in the background.

mCLASS early literacy assessment and intervention (K–8)

Effective universal screening and progress monitoring means that every student is an individual and targeted instruction should become a reality, not a dream. 

mCLASS® is the gold-standard K–8 assessment and intervention suite for early literacy that helps every child learn to read confidently.

  • Universal screening presented in one-minute measures shows where your students are, who is at risk, and where to target instruction.
  • Dyslexia screening identifies students who are at risk for reading difficulties without needing an additional assessment system
  • Elimination of manual assessment process gives you instant results and clear next steps for each student.
  • Progress monitoring allows you to quickly adjust to student needs, based on how they are responding to instruction.

The power of mCLASS

Based on decades of leading literacy research, mCLASS lets you know exactly which part of a skill a student is struggling with, then gives you effective next steps and lesson plans.

Watch how mCLASS can help teachers:

  • Save hours of time.
  • Catch at-risk students earlier.
  • Connect data to personalized learning.
Start exploring
Several students listening attentively

Amplify Core Knowledge Language Arts (PreK–5)

High-quality, content-rich instruction should combine multisensory phonics instruction with knowledge-rich texts and interactive multimedia resources.

Built on the Science of Reading, Amplify Core Knowledge Language Arts® (CKLA) sequences deep content knowledge with research-based foundational skills.

  • Explicit, systematic foundational skills lessons are easy to teach and exciting to learn.
  • Deep knowledge-building across units and grades helps access complex text, so real comprehension can happen.
  • Rich, authentic texts with engaging topics and immersive learning support students wherever they are.

Students love CKLA. But don’t just take our word for it.

Amplify CKLA is impactful for teachers, administrators, families, and most of all—students! Hear what students think about Amplify CKLA.

Start exploring
A young girl focuses on a laptop with a stack of books, a colorful creature, and autumn leaves in a stylized graphic.

Boost Reading (K–5)

Authentic personalized learning should be developmentally appropriate, grounded in research, and truly adaptive.

Boost Reading is a personalized, digital supplemental reading tool for grades K–5 featuring:

  • Research-based approach to critical literacy skill development that is proven to accelerate reading growth in just 30 minutes per week.
  • Captivating storylines and games with powerful individualized reading instruction and practice to bridge learning gaps while learning independently.
  • Actionable data that offers deeper insights into student performance and needs.

Boost Reading keeps all students playing and motivated to learn.

Boost Reading includes age-appropriate storylines that excite students’ curiosity. Regardless of their reading ability, students are placed in a year-long storyline that is developmentally appropriate for them. As students grow, so do the immersive worlds around them.

Start exploring
A student reading "Summer of the Mariposas"

Amplify ELA (6–8)

Amplify ELA is the only program truly designed to support middle school students at this critical developmental moment. We ensure that skills are taught, standards are covered, and the test is prepped – all while bringing texts to life and differentiating instruction.

  • Rich, complex text and research-based instruction at the center of every lesson to build the vocabulary, knowledge, and skills needed in middle school, high school, and beyond.
  • Multiple points of entry and differentiated support allow every student, regardless of fluency or ability, to engage deeply in the same curriculum.
  • Immersive digital apps that offer engaging interactive experiences where students work with key skills in brand new ways.

We are the program for middle schoolers.

Let’s face it– middle school students are different from high school students. That’s why they deserve a program of their own.

Start exploring
A futuristic cityscape with a figure in a red hood looking at a large digital billboard displaying a "wanted for unlawful reading" alert.

Boost Close Reading (6–8)

Middle school students need to exercise their close reading skills in order to deeply comprehend across the curriculum. Based on a riveting storyline designed especially for middle schoolers, Boost Close Reading helps students find deeper meaning in a digital journey like no other.

  • Inspire engagement via high-interest storytelling, choose-your-own adventure experiences, and skill-building features.
  • Explore topics like claim, evidence, reasoning, word choice, and tone in both literary and informational texts.
  • Detailed teacher dashboards display student progress, performance, and usage information, offering easy-to-access insights on areas of strength and weakness.

Fight the machines and save the world.

Before the machines took over, humans could fend for themselves. Now humanity is trapped. And their only hope? You.

Start exploring
A badge for EdReports Review Year 2023, two students at a computer, two students discussing with a tablet, and an educational diagram of a spider on a screen.

Amplify Science Pennsylvania (K–8)

Amplify Science Pennsylvania is a proven K–8 curriculum that develops critical thinkers who are prepared to solve problems in their communities and beyond. It features:

  • Phenomena-based exploration and three-dimensional learning where students take on the roles of scientists and engineers to solve real-world problems.
  • Immersive hands-on activities that teach students how to gather evidence, ask questions, and develop and defend claims.
  • Literacy-rich science instruction that enables young scientists to become excellent readers, writers, and speakers.
  • Custom lessons specifically designed to meet Pennsylvania’s STEELS standards.
Bar chart comparing science content knowledge: Do-Talk-Read-Write approach at 51.5% and Business-as-usual approach at 36.6%.

Do, Talk, Read, Write students outperform their peers.

Bar graph comparing middle school science vocabulary, showing 48.6% for the Do-Talk-Read-Write approach with Amplify Science and 22.5% for the Business-as-usual approach.

English language learners who use Do, Talk, Read, Write outperform their ELL peers.

Bar chart compares middle school science learning progression outcomes before and after a unit, showing similar distributions with the highest value at category 3 in both cases, illustrating the impact of Amplify Science instruction.

Do, Talk, Read, Write increases learning outcomes.

Start exploring

Get Support

Get support

Do you use already use an Amplify program in Pennsylvania? Our support team is here to provide technical and instructional support by phone, live chat, or email.

Get help now

Contact us

A woman with long brown hair and glasses wearing a light blue sweater, smiling at the camera against a gray background.

Julie Couch

District Enrollment <1800 students

A woman with long blonde hair and blue eyes is smiling at the camera, wearing a black top, in a well-lit indoor setting.

Jen Mee

Western PA

A smiling person with shoulder-length gray hair, wearing a peach-colored scarf and a gray sweater, stands against a plain white background. This image captures the essence of Pennsylvania teachers who are dedicated to enriching Science programs for elementary students.

Monica Vincent

Southeast PA

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Keenan Zambelli

Northeast & Central PA

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:

  1. 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
  2. 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

Student Data, which includes:

  • Roster Information
  • Demographic Data, such as race and national origin
  • School Records
  • Account Information
  • Schoolwork and Student Generated Content
  • Teacher Comments and Feedback
  • Device and Usage Data
  • To provide and improve our educational Products;
  • To support Schools’ 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 Users, or as otherwise permitted by Applicable Laws;
  • For adaptive or personalized learning features of the Products; provided that Student Data is not disclosed;
  • 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.

Authorized Users, which includes:

  • Contact Information
  • Account Information
  • Survey Responses
  • Device and Usage Data
  • For the purposes for which Student Data is used as set forth above;
  • For 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 K–12 students;
  • For internal research and analytics; and
  • As otherwise required or permitted, or as we may notify you at the time of collection.

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?

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.

Personal Information We Collect
How We Use Personal Information
Contact Information
  • To provide you with customer support and respond to inquiries.
  • To contact you with promotional emails (e.g. newsletters) or notifications related to the Site
  • To help us verify the identity of our user
  • As otherwise required or permitted by law, or as we may notify you at the time of collection
Account Information
  • To provide and manage the Site
  • To improve our products and services
  • As otherwise required or permitted by law, or as we may notify you at the time of collection
Payment Information
  • To complete your payment of purchases made through the Site
  • For internal operations (e.g. to improve and update our products)
  • For security and fraud prevention
  • As otherwise required or permitted by law, or as we may notify you at the time of collection
Information You Submit
  • To provide the Site and features to you, including to allow you to comment
  • To improve our products and services
  • As otherwise required or permitted by law, or as we may notify you at the time of collection.
Site Activity Information
  • We sell or share information about your Site activity with third parties for targeted advertisements on and off of Amplify. We also use this information to:
    • To provide and manage the Site
    • To improve our products and services
    • For internal operations (e.g. to improve and update our products)
    • For security, safety, and due diligence purposes
    • As otherwise required or permitted by law, or as we may notify you at the time of collection
Location Information
  • We use 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.
Inferences
  • We may make inferences about your interests and personal preferences (such as the content you like to consume). We also use this information to:
    • To personalize your experience on the Site
    • For internal operations (e.g. to improve and update our products)
    • As otherwise required or permitted by law, or as we may notify you at the time of collection

Some of the information described above may be considered “sensitive” under the laws of certain jurisdictions (including payment information and account login credentials (“Sensitive Information”). Whether information is Sensitive Information will depend on the laws of your jurisdiction. We only use Sensitive Information, such as payment information and account credentials for necessary or reasonably expected purposes – specifically, to provide you with our Services (i.e., fulfill purchases and to allow account logins).

Shine the Light

California’s Shine the Light law (Civil Code § 1798.83) permits California residents to request certain information regarding our disclosure of certain categories of personal information to third parties for their own direct marketing purposes in the preceding calendar year. We do not share personal information, as defined by California’s Shine the Light law, with third parties for their own direct marketing purposes.

Notice of Financial Incentive 

 As part of our services, there may be opportunities for you to complete surveys and questionnaires. As an incentive for completing the survey or questionnaire, you can voluntarily provide your personal information, which in turn enters you into a raffle drawing or enables us to provide you with 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 your survey is complete.

The value of the personal information we collect in connection with our Financial Incentives is equivalent to the value of the benefit offered.

2. Additional U.S. State Privacy Law Rights

Residents of certain U.S. states have the following rights, regarding your personal information (each of which are 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.
  • Correct. You have the right to request that we correct inaccurate personal information collected from you. 
  • Deletion. You can request that we delete your personal information that we maintain about you.
  • Opt-out (Do Not Sell or Share My Personal Information). Under several U.S. state privacy laws, consumers have the right to opt-out of the “sale” of their personal information (defined very broadly to include situations where we provide personal information to partners who provide advertising services to us) and the “sharing” of personal information in connection with the display of targeted advertising across third party websites. While we do not sell your personal information, we do share it in connection with our advertising efforts. Please also note that we do not knowingly sell or share the Personal Information of minors under 16 years of age.

We also honor the Global Privacy Control, a browser-based opt-out signal. We do not respond to other browser-based signals that do not meet applicable state law requirements, which may include older Do Not Track signals.

  • 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. 
  • Submission of Requests. You may exercise the above rights by emailing us at privacy@amplify.com. Note that we may deny certain requests, or fulfill a request only in part, based on our legal rights and obligations. For example, we may retain personal information as permitted by law, such as for tax or other record keeping purposes, to maintain an active account, and to process transactions and facilitate customer requests.
  • Authorized Agent. 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.
  • Verification. Whether you submit a request directly on your own behalf, or through an authorized agent, we will take reasonable steps to verify your identity prior to responding to your requests. The verification steps will vary depending on the sensitivity of the personal information and whether you have an account with us.
3. Notice for European Economic Area and United Kingdom Customers

As detailed at the beginning of our Privacy Policy (under the section titled “Our Role”), Amplify acts as a controller with respect to personal information collected as you interact with our Site.

Lawful Basis for Processing

We rely on the following lawful bases for our processing activities:

  • Consent;
    • We obtain your consent to collect and process device and usage data via cookies on our Site to understand how individuals use our Site and to help us measure the effectiveness of our advertising and marketing campaigns.
  • Pursuant to a contract with the user of our Site;
    • We process all categories of personal information that we collect to provide and manage our Site, including payment processing, where this is required in order for us to perform our obligations under our contract with you.
  • To comply with our legal obligations;
    • We process all categories of personal information that we collect to ensure the safety and security of our Site 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 rely on our legitimate interest to process all categories of personal information:
    • to provide, manage, and improve the Site where such activities are not strictly required under our contract, including personalizing your experience on the Site.
    • to ensure the safety and security of our Site where this is important but not required under the data protection law or cyber and information security laws.
    • to respond to queries or otherwise communicate with you in relation to our Site and the operation of our business where this is not strictly required under a contract with you.
    • internal research and certain marketing purposes (e.g. to periodically send newsletters and other promotional materials), which will not be based on Student Data or directed to K–12 students.

Your Data Subject Rights

If you are located in the EEA/UK, you have the following rights, 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

To exercise any of these rights, contact us as set forth in the section entitled “Contact Us” above and specify which European privacy right you intend to exercise. We may require additional information from you to allow us to confirm your identity. Please note that we store information as necessary to fulfill the purposes for which it was collected, and may continue to retain and use the information even after a data subject request for purposes of our legitimate interests, including to comply with our legal obligations, resolve disputes, prevent fraud, and enforce our agreements.

Complaints

If you have any issues with our compliance, 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.

Season 9, Episode 10

Phonology as a settled science, with Jane Ashby, Ph.D.

In this episode of Science of Reading: The Podcast, Susan Lambert is joined by Jane Ashby, professor in the Reading Science doctoral program at Mount St. Joseph University. The two define the concept of “settled science” as a jumping-off point before digging into phonology and the argument for not always basing your teaching practice on the newest research. Dr. Ashby touches on the impact of phonology on comprehension, the Matthew Effect, and why the term “instant words” is more accurate than “sight words.” You’ll walk away from this episode with two practical exercises Dr. Ashby recommends for teaching students to transfer oral segmenting and blending to reading and writing tasks.

Join Science of Reading: The Community to connect with fellow educators.

A smiling person with glasses and gray hair is featured in a circular frame against a background filled with book, pencil, and lightbulb icons, symbolizing the journey of reading and writing. This image perfectly illustrates themes from the Science of Reading podcast on teaching phonological awareness.
A button with the Apple Podcasts logo and text that reads "Listen on Apple Podcasts" on a white background, perfect for discovering science of reading training resources. Spotify logo with the text 'Listen on Spotify' inside a rounded rectangle on a white background.

Transcripts and additional resources:

Connect with Jane Ashby
Read: Phonological recoding and self-teaching: sine qua non of reading acquisition
More: The Four-Part Processing Model for Word Recognition
Read: Matthew effects in reading: Some consequences of individual differences in the acquisition of literacy
Join our community Facebook Group
Connect with Susan Lambert
Want to hear more of Dr. Ashby? Listen to the bonus episode!
Transcript

Meet Our Guest(s):

Jane Ashby, Ph.D.

Jane Ashby, Ph.D.

Dr. Ashby’s reading journey started 30 years ago. She pursued an Ed.M. at the Harvard Graduate School of Education, then taught adult learners who struggled with reading. This led her to deepen her instruction skills by studying the Orton-Gillingham approach at Massachusetts General Hospital. She supported teachers and students facing reading disorders in the Columbus area, then returned to school to study how readers get the words off the page during silent reading. She earned a doctorate in psychology from the University of Massachusetts, and in 2009, joined the Psychology Department at Central Michigan University, where her eye movement lab investigated the role of speech processes in silent reading. She coauthored the book Psychology of Reading (2012) as well as several papers examining the role of phonology in silent reading. During her sabbatical, Dr. Ashby supported teachers in Vermont who were developing more effective literacy practices. In her spare time, she enjoys reading and outdoor adventures.

Meet our host, Susan Lambert

Susan Lambert is the Chief Academic Officer of Elementary Humanities at Amplify, and the host of Science of Reading: The Podcast. Throughout her career, she has focused on creating high-quality learning environments using evidence-based practices. Lambert is a mom of four, a grandma of four, a world traveler, and a collector of stories.

As the host of Science of Reading: The Podcast, Lambert explores the increasing body of scientific research around how reading is best taught. As a former classroom teacher, administrator, and curriculum developer, Lambert is dedicated to turning theory into best practices that educators can put right to use in the classroom, and to showcasing national models of reading instruction excellence.

Person with short blonde hair, glasses, and earrings, wearing an orange jacket, smiling in front of a plain gray background—committed to literacy education and fostering background knowledge for all learners.

Quotes

“To store a vocabulary word, it's not enough to have the meaning. You have to have the entry for it, and the entry for it is the sound form of the word.”

—Jane Ashby

“The greatest gift you can give a kid is letting them know that you see that they're special and that they have something unique that they bring to the world. But the second piece is really, can you help them become a confident, independent reader?”

—Jane Ashby

“ The practitioner doesn't necessarily want to follow the latest research, because you don't know if the latest research is going to replicate or not. Is it going to hold up over time or not? If you always follow the latest research, you can find yourself zigzagging a lot in your practice.”

—Jane Ashby

“There's a good 10 to 20 years of solid work that needs to be done just implementing what we already know from research, what is already the settled science.”

—Jane Ashby

Amplify earns Digital Promise’s Research-Based Design Product Certification for Amplify Reading

Brooklyn, NY (February 10, 2020) — Amplify, a publisher of next-generation curriculum and assessment programs, was among only thirteen education companies awarded Digital Promise’s first Research-Based Design Product Certification for its commitment to consulting and incorporating research findings in its supplemental reading program, Amplify Reading.

The new product certification is intended to serve as a rigorous, reliable signal for consumers, including school administrators, educators, and families, looking for evidence of research-based educational technology products. 

“Schools and families want to know which edtech products can actually help students learn,” said Karen Cator, president and CEO of Digital Promise. “Digital Promise’s Product Certifications are designed to help strengthen consumers’ confidence in choosing research-based products, while recognizing product developers doing the important work of incorporating valid research into their designs.”

Amplify Reading is a K–8 supplemental reading program that provides students with practice and instruction in the underlying phonological awareness, phonics, vocabulary, comprehension, and close reading skills that are essential for fluent reading with strong comprehension. It engages and motivates a diverse array of learners with an adaptive story-driven adventure through a variety of activities, including mini-games, vocabulary practice, ebooks, and interactive instruction in close reading topics.

“Receiving this Digital Promise Product Certification solidifies Amplify’s commitment to all students across all entry points of learning, abilities, and demographics through intentional research methodology,” said Melissa Ulan, senior vice president and general manager, supplementals at Amplify. 

About Digital Promise
Digital Promise is a nonprofit organization that builds powerful networks and takes on grand challenges by working at the intersection of researchers, entrepreneurs, and educators. Digital Promise’s vision is that all people, at every stage of their lives, have access to learning experiences that help them acquire the knowledge and skills they need to thrive and continuously learn in an ever-changing world. For more information, visit the Digital Promise website and follow @digitalpromise for updates.

About Amplify
A pioneer in K–12 education since 2000, Amplify is leading the way in next-generation curriculum and assessment. Our captivating core and supplemental programs in ELA, math, and science engage all students in rigorous learning and inspire them to think deeply, creatively, and for themselves. Our formative assessment products turn data into practical instructional support to help all students build a strong foundation in early reading and math. All of our programs provide teachers with powerful tools that help them understand and respond to the needs of every student. Today, Amplify serves five million students in all 50 states. For more information, visit amplify.com.

Contact: media@amplify.com

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Desmos Math 6–8 receives perfect scores from EdReports

Brooklyn, NY – (December 15, 2022) Amplify, a publisher of next-generation curriculum and assessment programs, announced today that EdReports, the independent, nonprofit curriculum reviewer, awarded Desmos Math 6–8 perfect scores and an all-green rating for grades six through eight. Green ratings mean that materials met expectations for standards alignment and other indicators of quality, such as design and usability, after undergoing EdReports’ rigorous, educator-led reviews of curriculum programs.

Already beloved by a passionate teacher base,Desmos Math 6–8 became part of the Amplify suite of high-quality instructional programs last spring. With a focus on helping teachers celebrate student brilliance, build flexible mathematical understanding, and create the conditions for every student to be successful, the interactive lessons are standards-aligned, easy-to-use, and fully customizable by educators.

Students are presented with fun and delightful situations that spark curiosity, offer a variety of entry points into the content, and place student thinking and collaboration at the center of learning. Based on IM 6–8 Math™ by Illustrative Mathematics and Open Up Resources, Desmos Math 6–8 combines the best math content and technology to offer learning experiences that are intuitive, memorable, and effective.

​​”We have created a program that celebrates the best qualities of teachers and technology, using both to help students explore mathematics in depth,” said Eric Berger, senior vice president of Desmos Classroom at Amplify. “Our hope is that this distinction from EdReports allows us to bring this next-generation math program to even more teachers and students.”

About Amplify and Desmos Classroom
A pioneer in K–12 education since 2000, Amplify is leading the way in next-generation curriculum and assessment. In June 2022, Desmos split into two entities: “Desmos Studio,” a Public Benefit Corporation that builds and supports the Desmos Calculators, and “Desmos Classroom,” the team and technology behind Desmos Math 6-8. Together Amplify and Desmos Classroom are building a comprehensive core math curriculum called Amplify Desmos Math that will build off of Desmos Math 6–8 and be available for pilot and review in Fall 2023. Today, Amplify and Desmos Classroom serve more than 18 million students in all 50 states. For more information about Desmos Math 6-8, visit amplify.com/desmosmath. For more information about the in-development Amplify Desmos Math, visit amplify.com/math.

Contact: Kristine Frech; kfrech@amplify.com

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