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Website Terms of Use

Description of Site Services; Acceptance of Terms of Use

Welcome to www.amplify.com (together with any successor sites and the Site Services and Company Content (each as defined below), in whole and in part, the “Site”). The Site is operated by Amplify Education, Inc. (“Company” or “we”). The services that Company makes available on or through the Site include education-related articles, information and instructional services, purchasing functionality, support chat functionality and any other features, content, services, functionality and applications offered from time to time by Company on or through the Site (collectively, “Site Services”).

BY ACCESSING OR USING THE SITE, YOU REPRESENT AND WARRANT THAT YOU ARE OF LEGAL AGE TO ENTER INTO THIS TERMS OF USE AGREEMENT (“AGREEMENT”) AND YOU AGREE TO BE BOUND BY THE TERMS AND CONDITIONS OF THIS AGREEMENT. BY PURCHASING GOODS AND SERVICES ON THE SITE, YOU ARE ACCEPTING THE PRACTICES DESCRIBED IN THIS AGREEMENT AS WELL AS ANY ADDITIONAL TERMS OF USE THAT MAY BE ASSOCIATED WITH THE PARTICULAR GOODS AND SERIVICES YOU ARE PURCHASING.

Please read this Agreement carefully. If you are an employee or other representative of a school or other organization who is accessing or using the Site on behalf of such organization, then you are agreeing to this Agreement on behalf of yourself and such organization. We may modify this Agreement at any time in our discretion, and we may provide such modifications to you by any reasonable means, including by posting the revised version of this Agreement on the Site. You can determine when this Agreement was last revised by referring to the “LAST UPDATED” legend at the top of this Agreement. Your access to or use of the Site following any changes to this Agreement will constitute your acceptance of those changes. Notwithstanding the foregoing, any changes to this Agreement shall not apply to any dispute between you and us arising prior to the date on which we posted the revised version of this Agreement incorporating such changes or otherwise notified you of such changes. If you do not agree to be bound by this Agreement, you must not access or use the Site. Your access to and use of certain parts of the Site may require you to accept additional terms and conditions, and may require you to download certain Software or Content (each as defined below).

Jurisdictional Issues

The Site is controlled and operated by Company from the United States, and is not intended to subject Company to the laws or jurisdiction of any state, country or territory other than that of the United States. Company does not represent or warrant that the Site is appropriate or available for use in any particular jurisdiction other than the United States. In choosing to access and use the Site, you do so on your own initiative and at your own risk, and you are responsible for complying with all local laws, rules and regulations. You are also subject to United States export controls and are responsible for any violations of such controls, including any United States embargoes and other federal rules and regulations restricting exports. We may limit the Site’s availability to any person, geographic area or jurisdiction we choose, at any time and in our discretion. Not all products or services described on the Site are available in all states or territories.

Company content

The Site contains information, text, files, images, video, sounds, musical works, computer code, works of authorship, applications, and other materials and content (collectively, “Content”) of Company or its licensors (“Company Content”). The Site (including the Company Content) is protected by copyright, trademark, trade secret and other laws, and as between you and Company, Company owns and retains all rights in the Site. Company hereby grants to you a limited, revocable, non-sublicensable license, during the term of the Agreement, to access, display and perform the Company Content (excluding any computer code) solely for your personal, non-commercial use and solely as necessary to access and use the Site. Except as expressly permitted by Company in this Agreement or on the Site, you may not copy, download, stream, capture, reproduce, duplicate, archive, upload, modify, translate, create derivative works based upon, publish, broadcast, transmit, retransmit, distribute, perform, display, sell or otherwise use or transfer any Content. You may not, either directly or through the use of any device, software, online resource or other means, remove, alter, bypass, avoid, interfere with or circumvent any copyright, trademark or other proprietary notice on the Content or any digital rights management mechanism, device, or other content protection or access control measure associated with the Content.

User content

You may not access or use the Site for any commercial purpose. You are responsible for all Content that you post, upload, transmit, e-mail or otherwise make available on, through or in connection with the Site (collectively, “User Content”). Please choose carefully the Content that you make available on, through or in connection with the Site. Company does not control any Content other than Company Content, and as such you may be exposed to offensive, indecent, inaccurate or otherwise objectionable Content by accessing or using the Site. Company is not responsible or liable for any Content or the conduct of any Site user. If you become aware of any misuse of the Site, please report such misuse immediately to Company at general@amplify.com. Company reserves the right (but has no obligation) to monitor the Site, including for inappropriate Content or conduct, and to remove any Content in Company’s discretion and without liability to you or any third party.

Your proprietary rights

You retain any ownership rights that you have in your User Content. You hereby grant to Company and its affiliates, licensees and authorized users, a perpetual, non-exclusive, fully paid-up and royalty-free, sublicensable (through multiple tiers), transferable (in whole or in part), worldwide license to use, modify, excerpt, adapt, create derivative works and compilations based upon, publicly perform, publicly display, reproduce and distribute such User Content on, through or in connection with the Site and/or any other commercial or non-commercial endeavor of Company or any of its affiliates, including in connection with any distribution or syndication thereof to Third Party Services (as defined below), on and through all media formats now known or hereafter devised, for any and all purposes including promotional, marketing, trade and commercial purposes. The exercise of such rights shall not require any further permission or notice, payment or attribution to you or any third party. Company reserves the right to limit the storage capacity made available for User Content.

You represent and warrant that: (a) you own the User Content made available by you, or otherwise have the right to grant the license set forth in this Section, and (b) the posting of such User Content through or in connection with the Site does not violate the privacy rights, publicity rights, copyrights, contract rights or any other rights of any person or entity. You agree to pay for all royalties, fees and any other monies owing to any person or entity by reason of the use of such User Content.

Use of the site

You agree not to:

  • Post, upload or otherwise transmit or link to Content that is: unlawful; threatening; harmful; abusive; pornographic or includes nudity; offensive; harassing; excessively violent; tortious; defamatory; false or misleading; obscene; vulgar; libelous; hateful; or discriminatory.
  • Violate the rights of others, including patent, trademark, trade secret, copyright, privacy, publicity, contract or other proprietary rights.
  • Harass or harm another person.
  • Exploit or endanger a minor.
  • Impersonate any person or entity.
  • Introduce or engage in activity that involves the use of viruses, bots, worms, Trojan horses, Easter eggs, time bombs, spyware or any other computer code, files or programs that interrupt, destroy or limit the functionality of any computer software or hardware or telecommunications equipment, or otherwise permit the unauthorized access to or use of a computer or a computer network.
  • Interfere with, damage, disable, disrupt, impair, create an undue burden on, or gain unauthorized access to the Site or any Account, or Company’s servers or networks;
  • Restrict or inhibit any other person from using the Site (including by hacking or defacing the Site). Cover, remove, disable, block or obscure the Site (including advertisements on the Site).
  • Use technology or any automated system, such as scripts or bots, to collect user names, passwords, e-mail addresses or any other data from or through the Site, or to circumvent or modify any security technology or software that is part of the Site.
  • Send or cause to send (directly or indirectly) unsolicited bulk messages or other unsolicited bulk communications of any kind through the Site. If you do so, you acknowledge you will have caused substantial harm to Company, and that the amount of such harm would be extremely difficult to measure. As a reasonable estimation of such harm, you agree to pay to Company $50.00 for each actual or intended recipient of such communication.
  • Modify, adapt, translate, reverse engineer, decompile or disassemble the Site.
  • Solicit, collect or request any information for commercial or unlawful purposes.
  • Post, upload or otherwise transmit an image or video of another person without that person’s consent.
  • Use the Site to advertise, promote or engage in any commercial activity (including engaging in sales, contests or sweepstakes) without Company’s prior written consent.
  • Frame or mirror the Site without Company’s express prior written consent.
  • Use the Site in a manner inconsistent with any applicable law, rule or regulation.
  • Use any robot, spider, site search/retrieval application or other manual or automatic device to retrieve, index, “scrape,” “data mine,” or in any way gather content of the Site or reproduce or circumvent the navigational structure or presentation of the Site without Company’s express prior written consent. Notwithstanding the foregoing, Company grants to the operators of public search engines the permission to use spiders to copy material from the Site for the sole purpose of, and solely to the extent necessary for, creating publicly-available searchable indices of such material, but not caches or archives of such material. Company reserves the right to revoke these exceptions either generally or in specific cases.
  • Attempt, facilitate or encourage others to do any of the foregoing.

Company reserves the right to investigate and take appropriate legal action against anyone who, in Company’s discretion, violates this Agreement or attempts to do so, including terminating or suspending a user’s Account or access to or use of the Site, or reporting any User Content or conduct to law enforcement authorities.

You (and not Company) are responsible for obtaining and maintaining all telecommunications, broadband and computer hardware, equipment and services needed to access and use the Site, and for paying all charges related thereto.

User disputes

You are solely responsible for your interactions with other users of the Site, providers of Third Party Services (as defined below) or any other third parties with whom you interact on, through or in connection with the Site.

Purchases

Company may make available products and services for purchase through the Site, and may use third-party suppliers and service providers to enable e-commerce functionality on the Site. You may only purchase products and services that appear on the Site and that are delivered to an address located in the United States. You may only purchase products and services for personal, non-commercial use by you, your educational institution or students of your educational institution. We may limit quantities or refuse any order for any reason or no reason, including if we have reasonable cause to believe an order is for onward sale or resale other than through distribution channels approved by us. We make no promise that products or services available on the Site are appropriate or available for use in locations outside the United States, and purchasing products or services for delivery to or use in territories where their contents are unlawful is prohibited. If you choose to purchase products or services from locations outside the United States, you do so at your own risk. It is your responsibility to ascertain and obey all applicable local, state, federal and international laws (including minimum age requirements) in regard to the possession, use and sale of any product or service made available through the Site.

If you wish to purchase any product or service made available through the Site, you may be asked to supply certain information relevant to your transaction, including your credit card number, the expiration date of your credit card, your billing address and your shipping information. YOU REPRESENT AND WARRANT THAT YOU HAVE THE LEGAL RIGHT TO USE ANY CREDIT CARD(S) USED IN CONNECTION WITH ANY TRANSACTION. By submitting such information, you grant to Company the right to provide such information to third parties for purposes of facilitating the completion of transactions initiated by you or on your behalf. Verification of information may be required prior to the acknowledgement or completion of any transaction. While it is our practice to confirm orders by e-mail, the receipt of an e-mail order confirmation does not constitute our acceptance of an order or our confirmation of an offer to sell a product or service.

Details of the products and services available for purchase are set forth on the Site. All prices are displayed exclusive of all taxes and shipping/freight charges. Available payment methods, methods of shipping and shipping charges (including charges for expedited shipping, if available) are detailed on the Site. Company may also collect and remit sales tax on your purchase as required by United States law. If you are a tax-exempt entity, please enter the appropriate information where requested on your order form and we will not collect sales tax on your purchase.

Generally, credit and debit cards are not charged until we either ship the product(s) or confirm store availability (at which time you will be charged only for the products we have actually shipped along with any applicable taxes and shipping charges). However, we may pre-authorize your order amount with your credit or debit card issuer at the time you place the order, which may have an effect on your available credit line. When paying for a preorder with a debit card, you will be charged at the time you place your preorder. Please contact your credit or debit card issuer for more information. If you ordered a special delivery product, you will be charged once a delivery time is confirmed. For digitally delivered orders, your credit or debit card will be charged at the time that you initiate the download of the product.

All purchases made through the Site are made pursuant to a shipment contract. As a result, risk of loss and title for products purchased through the Site pass to you upon delivery of the products to the carrier. You are responsible for filing any claims with carriers for damaged and/or lost shipments. Please note that all shipping addresses must be compliant with the shipping restrictions contained on the Site.

Products, services and specifications

All products and services described or depicted on the Site, and all related features, content, specifications and prices, are subject to change at any time without notice. Certain weights, measures and similar descriptions are approximate and are provided for convenience purposes only. Packaging may vary from that shown. We make reasonable efforts to accurately display the attributes of our products, including the applicable colors; however, the actual color you see will depend on your computer system, and we cannot guarantee that your computer will accurately display such colors. The inclusion of any product or service on the Site at a particular time does not imply or warrant that such product or service will be available at any time. Occasionally, the manufacture or distribution of a certain product or service may be delayed for a number of reasons. In such event, we will make reasonable efforts to notify you of the delay and keep you informed of the revised delivery schedule. By placing an order, you represent that the products and services ordered will be used only in a lawful manner. All DVDs and similar products are sold for private, non-commercial home use (where no admission fee is charged), non-public performance, or classroom or instructional use only, and may not be duplicated.

Return and exchange policy

Unless otherwise specified in the terms associated with a particular product, you may return or exchange any product purchased through the Site within fourteen (14) days of receipt, by calling our customer service hotline, 1–800–823–1969, in the event that the purchased product is defective or you received the wrong product. Except for the foregoing, you may not return, cancel or exchange any product or service. Certain jurisdictions may provide additional statutory rights. Nothing herein is meant to limit your return or cancellation rights under local law. In the event that a return or exchange is due to an incorrect order or faulty product, we will be responsible for the shipping costs associated with such return. We will ship a replacement product upon receiving your defective or incorrect product and verifying the reason for the return or exchange.

Accuracy of information

We attempt to ensure that information on the Site is complete, accurate and current. Despite our efforts, the information on the Site may occasionally be inaccurate, incomplete or out of date. We make no representation as to the completeness, accuracy or currency of any information on the Site. For example, products or services included on the Site may be unavailable, may have different attributes than those listed, or may carry a different price than that stated on the Site. If an item’s correct price is higher than our stated price, we will, at our discretion, either contact you for instructions before shipping or cancel your order and notify you of such cancellation. Items in your “Shopping Bag” reflect the current price displayed on the item’s product detail page. Please note that this price may differ from the price displayed when the item was first placed in your Shopping Bag. In addition, we may make changes in information about price and availability without notice.

Chemicals, agricultural materials, and other hazardous materials

Certain products made available through the Site may include chemicals, agricultural materials or other material that may be subject to regulations or restrictions with respect to import or export, or to whom we may sell such material or where or how such material may be used. It is your responsibility to read and abide by all warning notices that accompany any products that you purchase. In addition, we reserve the right to request additional information from you, verify your identity, limit sales to certified educational or research institutions, or cancel or delay your order if required by law or if we believe it is necessary or advisable. Due to special shipping and handling requirements, freight companies routinely impose a surcharge on each package of hazardous material shipped. In such event, we will add such surcharge to your order.

Registration and account security

You may have the ability to create an account on or through the Site (an “Account”). If you submit registration information to create an Account, you represent and warrant that all information submitted to Company in connection with such registration is complete and accurate, and that you will update such information if it changes. If you create an Account, you are responsible for all use of your Account, and for maintaining the confidentiality of the information used to access your Account (including user name and password). You agree not to share your user name or password with anyone, or use anyone else’s Account at any time. You agree to notify Company immediately if you suspect any unauthorized use of, or access to, your Account (including your user name and password). You acknowledge that the reuse of your password in connection with accounts on other websites increases the risk that the security of your Account may be compromised.

The Site may make available, or third parties may provide, links to other websites, applications, resources, advertisements, Content or other products or services created, hosted or made available by third parties (“Third Party Services”), and such third party may use other third parties to provide portions of the Third Party Service to you, such as technology, development or payment services. When you access or use a Third Party Service, you are interacting with the applicable third party, not with Company, and you do so at your own risk. Company is not responsible for and makes no warranties, express or implied, as to the Third Party Services or the providers of such Third Party Services (including the accuracy or completeness of the information provided by such Third Party Service or the privacy practices of any third party). Inclusion of any Third Party Service or a link thereto on the Site does not imply approval or endorsement of such Third Party Service. Company is not responsible or liable for the content or practices of any Third Party Service or third party, even if such Third Party Service links to or is linked by the Site, and even if such Third Party Service is operated by an affiliate of Company or a company otherwise connected with us or the Site

Feedback

Unless we expressly agree otherwise in writing, if you provide us with any ideas, proposals, suggestions or materials (“Feedback”), whether related to the Site or otherwise, you hereby acknowledge and agree that (a) your provision of any Input is gratuitous, unsolicited and without restriction and does not place Company under any fiduciary or other obligation; and (b) any Feedback is not confidential and Company has no confidentiality obligations with respect to such Feedback.. You hereby grant to us a world-wide, royalty-free, fully paid-up, exclusive, perpetual, irrevocable, transferable and fully sublicensable (through multiple tiers) license, without additional consideration to you or any third party, to reproduce, distribute, perform and display (publicly or otherwise), adapt, modify and otherwise use and exploit such Feedback, in any format or media now known or hereafter developed, and you hereby represent and warrant that you have all necessary rights to grant the foregoing license. We may use Feedback for any purpose whatsoever without permission or notice, compensation or attribution to you or any third party. You are and remain responsible and liable for the content of any Feedback.

Privacy

Please review the Privacy Policy for the Site, available at http://www.amplify.com/privacy, to learn about our information collection, usage and disclosures practices with respect to information collected by us through the Site. Please note that certain products or services made available by us, other than the Site, may be subject to different privacy policies. In addition, the Site’s Privacy Policy does not address, and we are not responsible or liable for, the information collection, usage and disclosures practices of any third party or Third Party Service.

Disclaimers

THE SITE, USER CONTENT, THIRD PARTY SERVICES, AND ALL PRODUCTS AND SERVICES SOLD THROUGH THE SITE (COLLECTIVELY, THE “SITE PRODUCTS”) ARE MADE AVAILABLE “AS-IS” AND “AS AVAILABLE” AND COMPANY DOES NOT GUARANTEE OR PROMISE ANY SPECIFIC RESULTS FROM USE OF THE SITE PRODUCTS. COMPANY AND ITS AFFILIATES EXPRESSLY DISCLAIM ANY WARRANTIES AND CONDITIONS OF ANY KIND, WHETHER EXPRESS OR IMPLIED, INCLUDING THE IMPLIED WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT. IN PARTICULAR, COMPANY AND ITS AFFILIATES MAKE NO WARRANTY THAT THE SITE OR USER CONTENT OR THIRD PARTY SERVICES, OR YOUR ACCESS TO OR USE THEREOF, WILL BE UNINTERRUPTED, TIMELY, SECURE, ERROR-FREE, ACCURATE OR RELIABLE. UNDER NO CIRCUMSTANCES SHALL WE BE LIABLE FOR ANY CONSEQUENCES OF ANY UNAUTHORIZED USE OF THE SITE PRODUCTS THAT VIOLATES ANY APPLICABLE LAW OR REGULATION. CERTAIN STATE LAWS DO NOT ALLOW LIMITATIONS ON IMPLIED WARRANTIES OR THE EXCLUSION OR LIMITATION OF CERTAIN DAMAGES. IF THESE LAWS APPLY TO YOU, SOME OR ALL OF THE ABOVE DISCLAIMERS, EXCLUSIONS, OR LIMITATIONS MAY NOT APPLY TO YOU, AND YOU MIGHT HAVE ADDITIONAL RIGHTS.

Under no circumstances will Company or its affiliates be responsible for any loss or damage, including property damage, personal injury or death, resulting from use of the Site, Products, problems or technical malfunction in connection with use of the Site, Products, attendance at any Company event or the conduct of any Site users, whether online or offline. Your use of the Site, Products is solely your responsibility and at your own risk. The User Content and Third Party Services do not necessarily reflect the opinions or policies of Company or its affiliates.

Limitations on liability

IN NO EVENT WILL COMPANY OR ITS AFFILIATES BE LIABLE TO YOU OR ANY THIRD PARTY FOR ANY INDIRECT, CONSEQUENTIAL, EXEMPLARY, INCIDENTAL, SPECIAL OR PUNITIVE DAMAGES, INCLUDING LOST PROFIT DAMAGES, ARISING FROM YOUR USE OF THE SITE PRODUCTS, EVEN IF COMPANY OR ONE OF ITS AFFILIATES HAS BEEN ADVISED OF THE POSSIBILITY OF SUCH DAMAGES. NOTWITHSTANDING ANYTHING TO THE CONTRARY CONTAINED HEREIN, THE TOTAL LIABILITY OF COMPANY AND ITS AFFILIATES TO YOU FOR ANY CAUSE WHATSOEVER AND REGARDLESS OF THE FORM OF THE ACTION, WILL AT ALL TIMES BE LIMITED TO THE AMOUNT PAID, IF ANY, BY YOU TO COMPANY FOR THE SITE PRODUCTS.

Indemnity

You agree to indemnify and hold harmless Company, its affiliates, subcontractors and other partners, and each of their respective officers, agents, partners and employees, from any losses, costs, expenses (including reasonable attorneys’ fees), liabilities, claims or demands, due to or arising out of your use of the Site, your breach or alleged breach of this Agreement, your violation or alleged violation of any rights of another, or any Content that you post or otherwise submit on, through or in connection with the Site.

Termination

This Agreement remains in full force and effect while you access or use the Site. If you create an Account, you may terminate your Account at any time, for any reason, by contacting us at general@amplify.com. Company may terminate or suspend your Account and/or your access to or use of the Site at any time, for any or no reason, with or without prior notice or explanation, and without liability. Upon any such suspension or termination, your right to access and use the Site will immediately cease, and Company may immediately deactivate or delete your Account and all files and other information associated with it, and/or bar any further access to such files and other information. Company shall not be liable to you or any third party for any suspension or termination of your Account or of access to or use of the Site or any such files or other information, and shall not be required to make such files and other information available to you after any such suspension or termination. Sections 2, 5, 13, 17, 18, 19, 22, and 26 shall survive any expiration or termination of this Agreement.

U.S. export controls

All software made available in connection with the Site (“Software”) may be subject to United States export controls. No Software may be downloaded from or through the Site or otherwise exported or re-exported in violation of U.S. export laws.

Governing law

The terms of this Agreement are governed by the laws of the State of New York, U.S.A., without regard to its conflicts of law provisions, and regardless of your location.

Arbitration

EXCEPT FOR DISPUTES THAT QUALIFY FOR SMALL CLAIMS COURT, ALL DISPUTES ARISING OUT OF OR RELATED TO THIS AGREEMENT, WHETHER BASED IN CONTRACT, TORT, STATUTE, FRAUD, MISREPRESENTATION OR ANY OTHER LEGAL THEORY, WILL BE RESOLVED THROUGH FINAL AND BINDING ARBITRATION BEFORE A NEUTRAL ARBITRATOR INSTEAD OF IN A COURT BY A JUDGE OR JURY, AND YOU AGREE THAT COMPANY AND YOU ARE EACH WAIVING THE RIGHT TO TRIAL BY A JURY. YOU AGREE THAT ANY ARBITRATION UNDER THIS AGREEMENT WILL TAKE PLACE ON AN INDIVIDUAL BASIS; CLASS ARBITRATIONS AND CLASS ACTIONS ARE NOT PERMITTED AND YOU ARE AGREEING TO GIVE UP THE ABILITY TO PARTICIPATE IN A CLASS ACTION.

Arbitration procedure

Any arbitration under Section 23 above will be administered by the American Arbitration Association under its Commercial Arbitration Rules and Supplementary Procedures for Consumer-Related Disputes (“Supplementary Procedures”), as amended by this Agreement. The Supplementary Procedures are available online at http://www.adr.org/aaa/ShowPDF?doc=ADRSTG_015820. The arbitrator will conduct hearings, if any, by teleconference or videoconference, rather than by personal appearances, unless the arbitrator determines upon request by you or by us that an in-person hearing is appropriate. Any in-person appearances will be held at a location which is reasonably convenient to both parties with due consideration of their ability to travel and other pertinent circumstances. If the parties are unable to agree on a location, such determination should be made by the AAA or by the arbitrator. The arbitrator’s decision will follow the terms of this Agreement and will be final and binding. The arbitrator will have authority to award temporary, interim or permanent injunctive relief or relief providing for specific performance of this Agreement, but only to the extent necessary to provide relief warranted by the individual claim before the arbitrator. The award rendered by the arbitrator may be confirmed and enforced in any court having jurisdiction thereof. Notwithstanding any of the foregoing, nothing in this Agreement will preclude you from bringing issues to the attention of federal, state, or local agencies, and, if the law allows, they can seek relief against us for you.

Employment opportunities

Company may, from time to time, post Company employment opportunities on the Site and/or invite users to submit resumes to Company. If you choose to submit your name, contact information, resume and/or other personal information to Company in response to such employment listings, you are authorizing Company to use this information for all lawful and legitimate hiring, employment and other business purposes. Company also reserves the right, at its discretion, to forward such information to Company’s affiliates for their legitimate business purposes. Nothing in this Agreement or contained on the Site will constitute a promise by Company to review any such information, or to contact, interview, hire or employ any individual who submits such information.

The Digital Millennium Copyright Act of 1998 (“DMCA”) provides recourse for copyright owners who believe that material appearing on the Internet infringes their rights under U.S. copyright law. If you believe that any material residing on or linked to from the Site infringes your copyright, please send (or have your agent send) to Company’s Copyright Agent a notification of claimed infringement with all of the following information: (a) identification of the copyrighted work claimed to have been infringed, or, if multiple copyrighted works are covered by a single notification, a representative list of such works; (b) identification of the claimed infringing material and information reasonably sufficient to permit us to locate the material on the Site (such as the URL(s) of the claimed infringing material); (c) information reasonably sufficient to permit us to contact you, such as an address, telephone number, and, if available, an e-mail address; (d) a statement by you that you have a good-faith belief that the disputed use is not authorized by the copyright owner, the copyright owner’s agent or the law; (e) a statement by you that the above information in your notification is accurate and a statement by you, made under penalty of perjury, that you are the owner of an exclusive right that is allegedly infringed or are authorized to act on such owner’s behalf; and (f) your physical or electronic signature. Company’s Copyright Agent for notification of claimed infringement can be reached as follows: Copyright Agent, Amplify Education, Inc., 55 Washington Street, Brooklyn, NY 11201; Facsimile: 212-796-2311; Attn: Legal. Company’s Copyright Agent for notification of claimed infringement can also be reached electronically at: legal@amplify.com. Company reserves the right to terminate infringers’ and suspected infringers’ Accounts or their access to or use of the Site.

Notice for California residents

Under California Civil Code Section 1789.3, California users are entitled to the following consumer rights notice: If you have a question or complaint regarding the Site, please contact us by writing to Amplify Education, Inc., 55 Washington Street, Brooklyn, NY 11201 or by calling us at 212–213–8177 or sending a fax to 212–796–2311. California residents may reach the Complaint Assistance Unit of the Division of Consumer Services of the California Department of Consumer Affairs by mail at 1625 North Market Blvd., Sacramento, CA 95834, or by telephone at (916) 445–1254 or (800) 952–5210.

Other terms

This Agreement does not, and shall not be construed to, create any partnership, joint venture, employer-employee, agency or franchisor-franchisee relationship between you and Company. You may not assign, transfer or sublicense any or all of your rights or obligations under this Agreement without our express prior written consent. We may assign, transfer or sublicense any or all of our rights or obligations under this Agreement without restriction. The failure of Company to exercise or enforce any right or provision of this Agreement will not operate as a waiver of such right or provision. The Section titles in this Agreement are for convenience only and have no legal or contractual effect. References to and mentions of the word “include,” “includes,” “including,” or “e.g.” will mean “including, without limitation.” References to “discretion” will mean “sole discretion.” This Agreement operates to the fullest extent permissible by law. If any provision of this Agreement is unlawful, void or unenforceable, that provision is deemed severable from this Agreement and does not affect the validity or enforceability of any remaining provisions. Without limitation, you agree that a printed version of this Agreement and of any notice given in electronic form shall be admissible in judicial or administrative proceedings based upon or relating to this Agreement to the same extent and subject to the same conditions as other business documents and records originally generated and maintained in printed form. Company will not be responsible for failures to fulfill any obligations due to causes beyond its control.

Please contact us at legal@amplify.com with any questions regarding this Agreement.

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.

S1-01: The journey from student to SpaceX engineer: Juan Vivas

Illustration of Earth with text about a podcast episode featuring Juan Vivas, discussing the journey from student to SpaceX engineer. Includes a photo of a smiling person in a suit.

In this episode, we join Eric Cross as he talks to supply chain engineer Juan Vivas of SpaceX about his experiences growing up as a Latino in STEM. Juan shares his story of moving to the United States to study engineering and becoming successful in his career as a scientist. Juan openly discusses the experiences that made a difference in his life and the teachers that inspired him along the way. He also shares his experience as an engineer in different fields, as well as what it’s like to work in the supply chain during COVID.

Explore more from Science Connections by visiting our main page.

Download Transcript

Juan Vivas (00:00):

But to me, based on my experience so far, I think the best way to put it: An engineer is a technical problem-solver.

Eric Cross (00:28):

Welcome to Science Connections. I’m your host, Eric Cross. My guest today is Juan Vivas. Juan is a supply chain engineer for SpaceX. His career in STEM has pivoted from chemical engineering to working on foods like Cinnamon Toast Crunch to his current role at SpaceX, where he’s responsible for his work on Starlink, a technology that uses low-orbit satellites to provide internet access across the world. In this episode, Juan shares his story of how he became an engineer and how a thoughtful teacher used robotics to inspire him. I hope you enjoy this great conversation with Juan Vivas. Juan, thanks for being here.

Juan Vivas (01:14):

Yeah, yeah, of course! Super-excited to be here.

Eric Cross (01:19):

Hey, and starting off, I kind of like to ask your origin story. We were talking earlier about Marvel, and your journey of one working for…what I consider the closest thing that we have to SHIELD in the Marvel stories is SpaceX. Like with my own students, we talk about SpaceX like it’s a fictional thing, and we watch the rocket launches together and we watch the recovery and it’s so cool.

Juan Vivas (01:45):

Yeah.

Eric Cross (01:46):

And so when I knew that we were gonna be able to talk to you, I was excited. Like, I felt like I was a kid.

Juan Vivas (01:51):

<Laugh>

Eric Cross (01:51):

So I’d love to hear your origin story of you ultimately landing at SpaceX. And begin wherever kind of seems most natural to you.

Juan Vivas (01:59):

Yeah, yeah, of course. You know, I wasn’t one of those kids at from a young age I said “Oh, I’m gonna be an engineer.” Right? “I want to go and build all these things.” Where I grew up, and the social circle that I had, a lot of people were like doctors or lawyers. Just figured, you know, I’ll go to med school and go down the same path that 90% of like everyone else was gonna take. But in high school, I actually got into robotics. And, kind of like I mentioned, I wanted to do med school, that is what I figured I would end up doing. And then I got into robotics in high school. And I think that was what really kind of like changed my perspective of what I wanted to do, because basically these competitions were just—it was full-on driven by students. So we designed, programmed, and manufactured, like, the entire robot itself. And so through that I ended up doing a summer engineering program at the University of Maryland, the summer before going into my senior year in high school. And there we worked on a competition with underwater robots. And so we spent the entire summer, kind of similar scenario, designing a robot, manufacturing it, programming it. And then in the end it was like a competition in the buoyancy tank with different teams. And, you know, I think one thing that was really neat about that experience is that I got to hear Dr. John C. Mathers, who is a Nobel Prize physicist, speak to us in a room with, like, only 10 high school students. And just hearing his experience of where he started and the accomplishment that he’s been able to do, down in the STEM path, was really neat. And that summer was my final decision that I’m “OK, I know I want to be an engineer.” What’s interesting is I ended up choosing chemical engineering, instead of mechanical, which a lot of people, you know, based on all the experience that led me up to be an engineer, they asked me why I didn’t choose mechanical engineering. And I think one of the reasons why I chose chemical engineering is it’s very process-based. So one thing needs to happen, and there’s different inputs to that one step, and that step has an end-to-end reaction to it, right? So certain things need to happen in step one in order for step two to occur. And however the inputs happen in step one, it’s gonna affect the rest of the process. Honestly, very different than what I thought it was really gonna be. But what’s neat about chemical engineering is that it’s one of the most versatile engineering majors that you can have. Chemical engineering, because you work with a lot of process bases. Everything has a process, right? Everything needs to start with step one, and with, you know, step 10, whatever. And it’s all about optimization and improvement along those processes. So you can really take chemical engineering principles and apply ’em to different areas of a career, which is essentially the experience that I had in college. I had three internships with Dow Chemical where I did environmental health and safety, production, and supply-chain improvement. I then did research and development with Clorox. And then I did manufacturing engineering with General Mills. So really different job roles, different aspects, but same methodology applied.

Eric Cross (05:36):

I feel like there’s so much that you just said, <laugh> and I was trying to always, “I wanna ask him about that!” And in there, what I heard was there was a real pivotable, pivot moment in your life. Was the club…or was it a club, the robotics program? Or was that a class?

Juan Vivas (05:53):

You know, it was actually…it was VEX Robotics, specifically.

Eric Cross (05:56):

It was VEX! OK. Yeah, yeah. Really popular. And they still have it; I think we actually have some downstairs. So it was a club, and not necessarily a formal environment, where you were able to build. And it’s both collaborative and competitive, right? Like, there’s both aspects.

Juan Vivas (06:11):

Yep. Yep.

Eric Cross (06:11):

And, and then you had access to one of the only two facilities in the country that have these…were they buoyancy tanks?

Juan Vivas (06:20):

Buoyancy tanks, yep.

Eric Cross (06:21):

And there’s this book, Malcolm Gladwell’s Outliers, and then another similar book called Balance. It talks about how some of these innovators, like Steve Jobs and, and Bill Gates, they had access to things that other people didn’t. So, like, Bill Gates, I think at the University of Washington, had a computer that, you know, no one else did. And Jobs had one at, like, Hewlett-Packard. So it gave you this awesome headstart, where you’re able to test things in a real-life environment that kind of transfers into real-world skills. And then a few internships, so like, internships and mentors. So you had these people in the industry or people who were front-runners that were able to pour into you and give you these opportunities. And so it’s really neat to see how a program that starts as a club, kind of a competitive thing that introduced you to it and hooked you, then led to unfolding all of these opportunities that ultimately led you up to being here. And there’s one part—in looking at your LinkedIn profile, there’s a couple of really cool things that stand out. There’s a lot of cool things, but there’s two that really stood out. So one, working at SpaceX, and we’ll talk more about that, but I wanna go to General Mills and Cinnamon Toast Crunch. Because Cinnamon Toast Crunch is amazing.

Juan Vivas (07:39):

Yeah.

Eric Cross (07:39):

And you were part of the supply chain for that. In my head, I’m thinking, OK, like, what is he like responsible for? Like, getting the cinnamon and sugar?

Juan Vivas (07:51):

<Laugh>

Eric Cross (07:51):

What was, what did your job entail, when you were running that?

Juan Vivas (07:55):

There, I didn’t even know what I was gonna be doing until my first day. It was just, whatever the business need is, that’s where you’re gonna be put. So this was actually a high-priority plan for General Mills. And the production line that made Cinnamon Toast Crunch was split up into processes. So you have, they call it the process-process side, which is like literally raw materials, like making the cereal from scratch, baking it, adding the sugar, and then sending it to be packaged. And then you have the packaging-process side. so I was then placed as a packaging process lead, for the packaging side of that production line. So I was accountable for two packaging lines that packed out Cinnamon Toast Crunch. And that is where—that was actually my first real, you know, call it “real job,” like graduated college, going straight into the industry. I was a process lead for the packaging side of Cinnamon Toast Crunch.

Eric Cross (08:54):

So you went from cereal to rockets, <laugh>, which which is an amazing trajectory to have.

Juan Vivas (09:03):

Yeah. Yeah.

Eric Cross (09:04):

And when you kind of mentioned, back in your story about medical school, and, you know, it’s kinda like, what you see people doing, and you’re “OK, this is what I think I wanna do.” And then we have a perception in our mind about what a certain job’s gonna be like. And then reality hits. I think a lot of—when I ask my students, “What do you wanna do?” They think, like, “lawyer!” and when they think “lawyer!” they’re like, “I’m good at arguing!” Right? And until they find—until they talk to some lawyers and they find out like what that career can look like.

Juan Vivas (09:28):

Yeah.

Eric Cross (09:28):

You’re not just in the courtroom showing off your arguing skills. But, like, an engineer, when I talk to my students about what does it mean to be an engineer, often it’s very linear. It’s “I build bridges,” or, you know, maybe cars, but you’re a supply chain engineer. And, and that’s something that I think, now more than ever, it’s probably an incredibly critical role, especially considering that all of these supply constraints. Can you—what is a supply chain engineer? And what does it look like in your day-to-day? How is engineering rolled into that?

Juan Vivas (10:03):

Yeah, yeah. I think that’s an excellent question. I, too, once thought that engineering was just “I’m gonna be actually making something physical,” and like being super engineer-y about it. But, to me, based on my experience so far, I think the best way to put it: An engineer is a technical problem solver. As a supply chain engineer, specifically right now in my role at SpaceX…you know, as you can guess, the supply chain in the entire world is crazy. There’s no raw materials anywhere, and nothing can ever get on time. And so what I work on is I help our suppliers develop processes to meet the design criteria that we set up for like a specific part. As my job as a supply chain engineer, it’s “Can I take this design and make it manufacturable?” Right? “Can I go to any supplier and can they actually make this to the tolerance that the design engineer set them to be?” Nine out of 10 cases, the answer is no, essentially, is the best high-level way to put it.

Eric Cross (11:10):

When you’re solving these problems, is it this iterative process of going back and forth? Or is it just this aha-moment when you finally figure things out? ‘Cause I imagine they’re coming up with a design; you’re going back and saying, “Can this be manufactured?” or “Can it be done?” They’re saying no 90% of the time. And then are you the one responsible for kind of iterating on this, or changing it and then going back to them and telling them, asking them, until you get a yes? Is that—

Juan Vivas (11:33):

Yep. Yep, yep. Exactly. So we go through a process called Design for Manufacturing, DFMing. And where I essentially take, you know, the design engineer’s proposal, and then I have conversations with the suppliers, and then, that’s where the iteration begins. Where we go back and forth, back and forth, until we kind of meet in the middle to have something that can be manufacturable. Most of the times, in my experience, suppliers will always tell you no, just because they always want something that is manufactured really easily. And so you just gotta learn through experience. Like, when are they actually telling you something that’s a fact, versus when they’re just trying to you know, get out of a tolerance, or that “all right, all right, they mentioned that would just like make their jobs a little bit more difficult.”

Eric Cross (12:17):

So I’m hearing like there’s soft skills that are woven into the technical skills that you also need to be able to have.

Juan Vivas (12:23):

Oh, yes, absolutely. Yeah. I think, you know, as an engineer—and this is something, again, that I feel like you can only learn through experience—you’re gonna see that it’s not just you working to solve this one problem. Especially for a supply chain engineer. You’re talking with marketing; you’re talking with an industrial design team; you’re talking with logistics; you’re talking with procurement, materials management—just a whole set of people that don’t necessarily have technical background. Right? So sometimes, depending on the audience that I’m targeting, I’m always very, very peculiar on what is my target audience, right? How can I—how deep in my technical knowledge do I need to go? Because if I just, you know, talk straight Engineer, they either don’t care or they’re gonna be really confused about what I’m saying. So there is a stronghold of soft skills that definitely go into engineering, which I think are really important to communicate, you know, to, let’s say, students that are really interested in engineering. So you can be extremely smart and intelligent and really good at problem-solving, but if you don’t have those soft skills that you apply in the real world—’cause in the real world, you’re never only gonna be working with engineers, no matter like where you’re at—so having those soft skills to be able to manage with different backgrounds and different sort of people and different ways of thinking, it’s, I feel, really critical, for, for an engineer in the real world.

Eric Cross (13:50):

No, I think that’s a great point. It reminds me of teaching! And so many other professions where your ultimate goal is to really pour into this person in front of you and help develop them and create a sense of inquiry and wonder and personal growth and inspiration. But you’re also working within constraints and people and relationships. You know, you have your other teachers, you have parents, you have administrators, you have a district, you have communities, stakeholders. You have all of these different dynamics that you have to kind of navigate in order to ultimately help this child thrive. Versus just, like, being in the classroom: “OK, I just got <laugh>, the hundred or 200 students, just you and me. That’s it.” But that’s not the real world. And there’s this report that came out, I think Google ran it, Project Oxygen and Project Aristotle, and they asked the question, “What are the most effective traits of a good team and a manager?” And the top seven skills were all soft skills. So it is like exactly what you’re saying, where, yeah, it’s great that you have this technical aptitude, but if you’re not able to work with other people, problem-solve together, work with people of different backgrounds and perspectives, then you’re gonna run into some roadblocks. And that kind of dovetails, like, looking at things like if you looked at education from the perspective of an engineer. So you’re all about optimizing, right? Optimizing, working with what you got. When you look at education, are there any things that you would optimize to help improve the experience of students? Like, looking back, that you would fine-tune, that you think could provide better outcomes in the classroom?

Juan Vivas (15:28):

You know, I feel…I don’t know. Obviously I’m not a teacher. And I’m sure teachers just have so much stuff going on. But I think just like, finding…giving a chance to those students that you see a lot of potential in and really taking the time to mold them. You know, I did have a teacher who was able to mold me and give me that kind of one-on-one personal experience, right? I think honestly to me it just comes down to mentorship, and motivating students on what, you know, they’re passionate for. Like, putting them in front of engineers, right? Like finding engineers to come volunteer and explain to them. I genuinely believe it just takes one spark to really get a student on a trajectory where they can make an impact in the future. So to me, it comes down to, really, exposure. How much are you really exposing your students to…you know what, something I’ve learned, when I joined SpaceX, is that Elon doesn’t believe—well, you know, there there’s a lot of things that Elon believes and not believes in; there’s a whole different type of conversation!—but he doesn’t think that you can just take a curriculum, let’s say, and just apply it massively to everyone and expect like everyone to be it. That’s just naturally not how it works, right? Students learn at different paces; they have different sort of interests. This is actually why he created his own school for his kids in LA, called Ad Astra. You know, if you take that mentality, what that school is doing is that they’re working at the students’ pace and at the student’s interests, right? And I actually have a coworker who has his kids in that school. And I mean, these are one of the most brilliant kids I’ve ever known. Like, they are taking differential equations in the eighth grade. And I didn’t know what differential equations was until I was in college already and they told me, “This is a class you have to take.” <Laugh>. But it’s finding that crossway where, where is the curiosity of the student? What are they really interested in? and exposing them to that.

Eric Cross (17:51):

Yeah. And what I’m hearing of that is, in teacher-speak, a lot of personalized learning. Like you were talking about…is it Ad Astra?

Juan Vivas (17:59):

Ad Astra? Yep.

Eric Cross (18:01):

Ad Astra. You know, every student learns in their own way and they develop knowledge in their own way. And being able to personalize learning according to the students’ abilities and needs, and then accelerate or slow down, really produces some amazing effects. I know this is something that we as teachers try to do with the classroom. Scaling it is the challenge. But it’s great because even with people who are in charge of policy or people who have decision-making ability, hearing people from the top down saying, “Hey, look, this is what worked for me. This is how I was able to become successful. I had a teacher that was able to be a mentor to me because they knew me, they had a relationship with me, they were able to tap into my passions and use those passions to drive me to do or put me in programs that I might not have known about because they, they knew who I was.” And it’s not one-size-fits-all for everyone. So having—maybe it’s curriculum or learning experiences that are kind of modular, where students are able to maybe try on different things and get that exposure, I’m a big, big believer, like you are, in mentorship. That was a huge, huge thing in my life. Having mentors. It’s the reason why I became a science teacher. In seventh grade, I had a mentor who had us doing college-level science, you know, at UC San Diego. And it completely changed the trajectory of my life, in a direction that I wouldn’t have had without him. So I think that’s great. And it’s something that we as teachers would appreciate hearing. Going back to what you said…earlier you said your wife is a supply chain engineer as well. And so that means that there’s two people who are process-minded in the household. And this is kind of a lighter question, but I gotta wonder, do you have the most optimized flow for grocery shopping? <Laugh> Because…

Juan Vivas (19:49):

Yeah, I think we don’t spend more than like 20 minutes at a grocery store. Mind you, we only shop at Trader Joe’s and we have a very specific list before going in. And if you ever shop at Trader Joe’s, you just know where everything is ’cause it’s always there and it’s small, right? But yeah, like we’re, we’re in and out in like 15, 20 minutes. It’s great.

Eric Cross (20:11):

I love it. I love it. I feel like I’m that way by design. I go in with a purpose and this is exactly what I want. I know where the cookie butter is, <laugh>, I know where my coffee is, and then, OK, I’m in and out. Apple Pay or whatever I’m using. And then we’re good to go. Do you think…so as someone listening to this or some people even just becoming aware of supply chain engineering, what advice would you give someone that’s interested in pursuing this career path? If you maybe reverse-engineered your process, knowing what you know now, you were gonna give advice, you were that mentor, what are just some kind of tips or ideas or thoughts or trajectories that you’d think that they should aim for? I’m assuming like robotics….

Juan Vivas (20:56):

Yeah. You know, I think I would say definitely finding some sort of program that exposes you to a lot of things that you won’t be exposed to, like on a day-to-day basis, or something that you just can’t be exposed to naturally at school. And mentorship, honestly. I was born in Colombia and my parents were both—they’re still both professionals, but they were both professionals in Colombia. And when we moved to this country, this was like December of 1999. My parents started from scratch, and so they didn’t really grow up in the States, right? So when it was my time to go to college and do all of this stuff, it was just like me on my own figuring this stuff out. And, you know, they definitely made some mistakes when it came to college applications and whatnot. But once I was in college, I knew that the best way for my success was gonna be through mentorship. And that’s when I joined the, Society of Hispanic Professional Engineers, which is a nationwide organization. And each college, well, most college campuses, have their own chapter. In joining that, I was exposed to resume workshops, mock interviews—basically how do you even talk to a recruiter? Which is so critical, right? And personally that that organization was really what molded my actual professional career.

Eric Cross (22:19):

There’s this theme that I’m hearing, kind of weaving through this. And in addition to—as we’re talking about STEM and technical skills, in addition to that, there’s this thread that I’m receiving of…being able to form relationships with other people, for our students, is an important skill to teach and should be taught explicitly. Which isn’t…it’s not really a curriculum, right? Like, you don’t get tested on your ability to….conflict resolution or how to write an email or how to develop a relationship. And then the other part in I think what you just said is the aspect of community. Through this organization, you learned kind of some of these hidden rules, maybe I would call it.

Juan Vivas (23:04):

Yep.

Eric Cross (23:04):

It’s not that you didn’t have the…you had the aptitude. You had the drive. But there were these kind of hidden rules, and from moving to the US, you needed a community to be able to show you, so that you can kind of go through the proper steps.

Juan Vivas (23:16):

Exactly.

Eric Cross (23:17):

And so that created a lot of value for you.

Juan Vivas (23:19):

Yep.

Eric Cross (23:20):

Well, the last question that I have is, is just kind of a wondering. You have this awesome story, and the story continues to unfold. I gotta say, <laugh> I’m gonna be following your LinkedIn profile, because I think you just have kind of the coolest trajectory of going from, you know, General Mills, working in chemical engineering, and then ultimately it’s SpaceX. And every time I see the rocket taking off and landing, I’m gonna be thinking, thinking about you. So cool!

Juan Vivas (23:47):

Yeah. Yeah.

Eric Cross (23:49):

And personally, I have a hope that one day, one of my students will be at a company, you know, like SpaceX or Tesla or wherever, and one day I get to interview them and talk to them and see what they say. But the last question I want to ask is, is there, is there a teacher who inspired you, or a memorable experience that you have that made an impact on you?

Juan Vivas (24:16):

Yeah, yeah, of course. It was kind of you know, middle school going into high school. The way my school worked, everything was divided from pre-kindergarten, whatever, first to sixth grade, and then seventh grade to 12th grade. So I had a high school science teacher, Ms. Brown, Ms. Velda Brown, who, came from a small little island town on the east coast of Canada. Somehow landed, in the high school that I went to, to teach science. Going back to the beginning of the story where I mentioned that I figured whatever, I’ll go to med school. I played soccer, basketball, and, you know, I said, “I’ll figure it out once I graduate.” It might have been like life science in the eighth grade or something like that. But then she went on to teach me chemistry and physics as well. And when I was in the 10th grade, she approached me and she asked me if I wanted to join the robotics club. And I remember saying robotics? I don’t know. You know, naturally, in school, it’s different sorts of crowds: people that play sports and people that are like in like STEM clubs or whatever. And I was, “Ah, I don’t know; I don’t know how I feel about robotics; not really my thing….” But somehow she convinced me to join robotics. It’s me, coming into this group of kids that already knew each other, and they were all working on robotics. And I’m, “Yeah, I mean, I guess I’m just here to try this thing out.” It was a thing where we met every single Saturday at like seven in the morning. And there were times where I literally had to choose, “Do I go to like a soccer game or do I go to you help my team with robotics?” And I completely loved it. Like, I fell in love with the aspect of building something from scratch, and just making it operative. And she ended up just being a huge mentor for me in high school, actually. With her, with the help of her, I ended up opening the robotics club at my school. And before I left, we opened it up to middle schoolers. And then, you know, later, years later down the road when I was in college, I found out that it was now a whole-school thing. So there was an elementary robotics club at the school, the middle school one, and then the high school one were still a thing like years after I left. And that was like just so amazing to hear. But yeah, it was Ms. Velda Brown, my high school science teacher, that really took her time to mold me and get me into robotics, and really mentor me. And honestly, I’m sure you as teachers, you guys probably hear about it a lot, but you can have a lot of power in shaping a kid by just telling—believing in them, right? She believed in me so much that I would go on to be a successful engineer. And I’m. “OK, yeah, yeah, you’re just saying it.” But she spoke life into her students up to this day. I still speak about it with my wife, and when I’m in conversations about this, that if it wasn’t for my high school science teacher, I would not—well, no, I would probably not be an engineer right now.

Eric Cross (27:38):

Wow. Shout out to Ms. Velda Brown <laugh>. Would you say she spoke…I think one thing that just resonated with me is when you said she “spoke life” into you.

Juan Vivas (27:46):

Yeah.

Eric Cross (27:46):

That was really powerful. And I think we as teachers have that power and we don’t realize it. Because, you know, we get so we’re so familiar and living day-to-day, but we do have the power of life, speaking life, into our young people. And, yeah, that was—

Juan Vivas (28:03):

Absolutely, yeah. You know, I think obviously people grew up with different backgrounds, different communities, life situations, right? So imagine having like a student that is similar in that environment and then they just hear someone at their school, like, “Hey, you’re really good at this. why don’t you consider doing this?” And that’s when I feel teachers have that power. Where like they don’t necessarily know the background, but they can make that opportunity, or make that decision in the moment, to really shape a student’s life.

Eric Cross (28:37):

And we need to hear that. And I think, I hope that other teachers listening to this will be reminded that many times we don’t get to reap the harvest. We don’t get to see the <laugh> Juan Vivases at SpaceX. They just kind of go, and they disappear, and we hope for the best, and we get a new group. But every once in a while they come back, and we get to see what our watering or seed-planting was able to produce. And so, just know that you sharing your story for educators, and for definitely Ms. Brown, makes a huge difference and is a huge encouragement. So.

Juan Vivas (29:11):

You know, I think we touched on earlier, you know, how do I end up going from cereal to rockets, right? And I think it ties along with what I mentioned earlier of just taking—as an engineer, you’re really a critical problem solver, right? And you think that methodology. And if you find a way, you can apply it to different sectors. When I was doing a lot of like the packaging process stuff at General Mills, being a lead on a high-volume manufacturing line, what I do for SpaceX specifically, right now, I’m actually on the Starlink project. So if you’re up to date with Starlink, it’s, it’s essentially high reliable, fast internet that we’re providing to areas where usually people don’t have access to internet, right? Or maybe they do, but it’s extremely expensive. Because to an internet provider company, the benefit is not there, if they extend an entire internet fiber line out to their place because it’s only directed to them, right? So that’s, that’s essentially what Starlink is trying to solve. And this is the first time that SpaceX is facing a consumer packaging scenario. Before it was just rockets. And now they’re selling a product to consumers. They had never done that before, especially in a high-volume manufacturing setting. And so I am the supplier development engineer for all the consumer-facing packaging for the Starlink product itself. And that’s essentially how all those thoughts connected, where I had this experience coming from General Mills and packaging high-volume manufacturing. And then when Starlink started, they’re all, “Right, well, who knows anything about packaging?” Right? “We know so much about rockets, we need someone with this technical background.” And that’s essentially how I bridge over to SpaceX.

Eric Cross (31:11):

And so while you’re working at SpaceX, you’re working on Starlink, which I know you mentioned that—you said that it’s providing internet globally, which in and of itself, we—especially those of us that live in major cities—we kind of take for granted. Internet is like a utility. But we don’t maybe realize that in many parts of the world, internet is not reliable or even accessible.

Juan Vivas (31:33):

Right. Right.

Eric Cross (31:34):

I see every once in a while, I think, the StarlinK satellites sometimes are visible?

Juan Vivas (31:38):

Yep.

Eric Cross (31:39):

Low orbit?

Juan Vivas (31:39):

Yeah. Yeah. You can go—they’ll kind of be like a little train of bright stars that move along together. Yep.

Eric Cross (31:46):

And that must—that must feel…I mean, we all have jobs and we’re all doing different things, but you’re working on a project and you’re engineering something that actually can provide a lot of opportunities or close a gap in some parts of the world where they don’t have access to internet. They’re gonna be able to have access and be connected all over. I dunno, the word would be “existential.” Existential value. Like, what you’re doing is actually providing a service for people. Humanity. Like, addressing a critical need in many, many places around the world.

Juan Vivas (32:26):

Yeah. We’ve had stories where we have sent Starlink kids to a small school in a village in rural Chile, right in South America. And for the first time ever, they’ve had internet. We have supported disaster relief in Europe. I think this past summer, Europe had really bad floods. We sent Starlink kits out there. You know, the vision of working at an Elon Musk company and SpaceX and Starlink—this is all stuff that is being done for the first time in history. We have never, ever done anything like this before until now. And to be able to provide those that don’t have the access to—to your point, it’s kind of wild, right? Like we, we just take it for granted. “Oh yeah, I just have internet. Let me log on.” There are people on Earth right now that have never been on the internet. Or don’t even know what the internet is. And that’s essentially the, the gap that Startlink is starting to close.

Eric Cross (33:26):

Yeah. We think about that while my students are doing TikTok dances. <Laugh> And there are people who, you know, never, never been connected. And, it kind of makes me more like, just inside, if I can ask: What’s it like working at SpaceX? I showed my students what it’s like working at some of the Silicon Valley companies. ‘Cause just to show them there’s slides and food and, you know, they kind developed this ecosystem inside so that it’s really kind of homey to kind of keep you there, you know. When you’re working and there’s bikes and things like that. And that’s a very Silicon Valley type of thing. But, you know, in listening to you talk about SpaceX and Elon, you know, you’re with a really visionary kind of company, and when I hear you talk about it, there’s I can hear this passion, this, “we’re doing something.” Is that culture, like, pervasive everywhere? Are you around folks that kind of are on that same wavelength? Because I definitely get it from you as you talk about what you do.

Juan Vivas (34:28):

Yeah, yeah. Definitely. I think, as an engineer, you know, going to SpaceX and working at SpaceX, it’s essentially—personally, I believe right now in the US it’s like the mecca of engineering, right? Like, it is where engineering in this most, you know, shape and manner, it’s being applied. I think what’s really interesting is that the way that Elon looks at it is just iterate, and iterate fast, right? Like, fail and fail fast. I think as an engineer, you always want to have things perfect, right? And so you spend a lot of time in making a decision or investigating something or whatever. And working at SpaceX is the complete opposite. It’s just you know, “Assume, state your assumptions—like, what are you assuming right now? What are the risk at it? And just make a decision and then see what the result is.” You know, so it’s an environment where you learn, really quick.

Eric Cross (35:28):

You said something that I think was powerful and I hope, I think <laugh>, this is definitely, I’m gonna get a clip of this <laugh> of you saying it. Because it speaks directly to, I think, what a lot of students struggle with in the classroom, is there’s this competition or feeling that you always need to be right. And you need to be right the first try, on the first time. And a lot of times it’s because students will compare themselves to each other, or there’s a tremendous amount of pressure to be successful. But you said, “Fail and fail fast, iterate, state your assumptions.” And it sounds like this critical part of being an engineer or in what you do, like there’s no room for ego or attaching your identity or your sense of value or worth or ability to whether you’re able to solve a problem in the first try.

Juan Vivas (36:13):

Yep.

Eric Cross (36:14):

Like, you have to be OK with the cycle, is kind of what I’m hearing from you. Is that, is that right?

Juan Vivas (36:19):

Yep. Exactly. It only took six months to develop the product from scratch and launch it to the public, which is insane. Nowhere in the world will any company ever iterate that fast and come up with a brand-new project. But it’s because of that mentality—like you’re saying, it’s not about like just trying to make it perfect and have all this information. And I think Elon has learned this personally, you know, through Tesla and the beginning of SpaceX. It’s, “I can wait to have all this information, and most likely I’m still gonna be wrong after I make the decision.” So it’s, “Might as well take the risk, do the decision, and then just see where you learn from it, right?” And then you keep applying that, applying that. So it’s like you iterate, iterate, iterate, iterate until you get what you want.

Eric Cross (37:00):

I think this is even, like, great advice. I’m taking this personally because I get paralysis by analysis <laugh>.

Juan Vivas (37:06):

Yep.

Eric Cross (37:07):

You know, I’ll research something to death but then not actually execute. Like, I need to make a decision and do it and then course-correct along the way. Somebody once told me it’s a lot easier to turn a moving car than it is a car that’s sitting still. And so as you’re kind of flowing, you’re just making these adjustments along the way until you end up on the path that you want to be. So I think that there’s so many gems in the things that you’re saying right now. What I’m thinking through the lens of my seventh graders that want to work in any STEM field—I mean, really, any field in general, but especially engineering, especially the STEM fields—knowing that, pick it, make a decision, move forward, and then course-correct along the way. That’s what science looks like in the real world.

Juan Vivas (37:49):

Yep. Exactly. Yep. And definitely most important—and I feel like this is sometimes where, not necessarily education in general, but it’s just, we want students to, “OK, you need to get it right the perfect time, right?” But it’s like, every student is gonna think differently. A student is gonna take a different assumption based on their background and experiences. And I mean, you know, we can go a lot deeper in that, but the way a student is shaped, they’re gonna take certain assumptions. So that’s where it gets interesting. OK, why are you assuming that? Where’s your thought process in this?

Eric Cross (38:25):

And we all come from different backgrounds and mindsets and filters and biases that cause us to look at something a certain way. And it’s not just like calling it out, just going, “Hey look, this is what it is.” Like autopsy without blame, this is what I’m working with. Let’s discuss it openly. Right? And if we started that process earlier, you know, younger, in classrooms, we can de-stigmatize the right answer being the best answer more, as opposed to focusing on process as opposed to outcome. And then you kinda get used to wanting to go through the process. I look at it like video games and I talk to my students. I say, “You know, you don’t pick up a video game that’s brand-new and then play it and then you die once and you’re ‘Ah, I’m never gonna play this game again.’ You know, it just doesn’t work that way. You’re going through this iterative process, and no matter what you play, you’re trying things differently. You’re data collecting. And then you’re making new decisions based on the data that you collected.” And for some of my kids, they’ll just raise their hands, say, “No, I just get mad and throw the controller across the room.” <Laugh> But I go, “Yeah, and then you’ll try it again.”

Juan Vivas (39:33):

The best way to know how not to do something is to fail. And so you already…I mean, what is that famous quote? I think that’s why Thomas Edison’s, “Oh, I, did not fail 99 times. Right? I only found 99 times…” I mean, that is that is true. And I feel like at work in a SpaceX, that is something that probably the core of it comes from there. It’s you know, any failure, quote unquote, that you may take it as a failure, it’s really not. You’re just “OK, we, we tried that. It didn’t work. Like what are we gonna do next?” So it’s just like taking that learning and like moving off with it quickly.

Eric Cross (40:09):

I heard a couple of teachers say, “Things fail: First Attempt In Learning: F A I L.” And then another teacher, one of my mentor teachers, she said, “There’s no such thing as failure, just data, in science.”

Juan Vivas (40:20):

Mm-hmm. <affirmative>. Exactly. Yep.

Eric Cross (40:23):

And so I’ve always taken that to heart. And I share that with my own students, just, “A ‘no,’ a lot of times, will tell you more information than a ‘yes.’” ‘Cause if something works in the first try, you may not exactly know why it worked. It just did.

Juan Vivas (40:34):

Yeah. Yep.

Eric Cross (40:37):

So yeah. Well, I went on your time, brother. Dude. <laugh>. The time flew. It was…

Juan Vivas (40:46):

Yeah.

Eric Cross (40:47):

There were so many things I was trying to write out as you were talking, that I just felt like, “This guy is sharing so many gems!” But yeah, I want to thank you for taking time outta your day and for sharing that information for your passion for what you do. And, I don’t know, I think that students and teachers that listen to this will get an insight from a perspective that really matters. ‘Cause ultimately we’re, we’re trying to really prepare our students for real life. Maybe I’ll email you privately if I order a Tesla, if you can move me higher up the Cybertruck line. <laugh>

Juan Vivas (41:22):

Yeah. No promises.

Eric Cross (41:24):

<laugh>

Juan Vivas (41:25):

Yeah. No, I appreciate you guys having me, having me here, and be able to speak on my experience. And hopefully it sparks a couple, one, even if it’s just one teacher that will spark another student, that is already success there. So.

Eric Cross (41:42):

Well I know, I know what you said resonates with me and it fills my cup. And I’m excited. So I’m already thinking of some ideas of things that I can do, just because of this conversation, and I know other people will as well. And, again, this is Juan Vivas, who’s a supply development engineer at SpaceX. He’s worked at some amazing places. And someone who believes deeply in not only the power of the technical skills, but the heart skills, and how community makes a huge impact in his life. It made a huge impact in him ultimately becoming a scientist, and now working on a project at SpaceX, Starlink, that is going to provide access to the world, to the web. And that’ll ultimately help us solve more problems and innovate and create some solutions that will benefit everybody. Thank you, sir. Appreciate you.

Juan Vivas (42:30):

Yeah, thank you. Thank you so much, Eric. Appreciate it.

Stay connected!

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

What Juan Vivas says about engineering

“Based on my experience so far, I think the best way to put it… an engineer is a technical problem solver.”

– Juan Vivas

Supplier development engineer, SpaceX

Meet the guest

Juan Vivas is a chemical engineer currently working as a Supplier Development Engineer at SpaceX. Juan got his start at the University of Florida, where he led the Society of Hispanic Engineers (SHPE) as vice president. He’s worked for companies like Clorox, Dow Chemical, and General Mills. Juan lives in Los Angeles, California with his wife and two dogs.

Man in a suit and tie smiling at the camera with a blurred green background.

About Science Connections: The podcast

Welcome to Science Connections: The Podcast! Science is changing before our eyes, now more than ever. So…how do we help kids figure that out? We will bring on educators, scientists, and more to discuss the importance of high-quality science instruction. In this episode, hear from our host Eric Cross about his work engaging students as a K-8 science teacher.

You might also like:

Podcast cover featuring Eric Cross smiling. Text reads: "Science Connections. Season 1 | Episode 0. Eric Cross. About Science Connections: The Podcast." Science-themed graphics surround the text.

Science Connections Teaser

Listen now! Science Connections Trailer Episode

An array of educational cards featuring diverse children engaged in science activities, each card highlighting a different science-related profession.

STEM Career Cards

Inspire your students with STEM careers all around them!

Three children of backgrounds smiling and holding a robot, with the title "best science podcasts" above them in a colorful, cartoon style illustration.

Free ebook: How to Train Your Robot

Integrate science and literacy by introducing your young readers to cutting-edge…

Welcome, Idaho K-8 Science Reviewers!

Thank you for taking the time to review Amplify Science. On this site, you’ll find all the resources you need to learn more about this engaging and robust NGSS program. Below, you will also have the opportunity experience our program firsthand with a demo account to access the digital platform.

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

Collage of educational settings: top left, two young girls using laptop in library; bottom right, middle school science project display on tablet; bottom left, two boys with tablet discussing.

Overview

With Amplify Science, students don’t just passively learn about science concepts. Instead, they take on the roles of scientists and engineers to actively investigate and make sense of real-world phenomena. They do this through a blend of cohesive and compelling storylines, hands-on investigations, collaborative discussions, literacy-rich activities, and interactive digital tools.

Listen to these educators share how the program empowers students to think, read, write, and argue like real scientists and engineers every day.

Grades K–5

Grades 6–8

Amplify Science Grades K-5 Tour for Idaho Educators

Amplify Science Grades 6-8 Tour for Idaho Evaluators

Proven to work

Click here to read about the efficacy and impact of Amplify Science.

Two young girls sit on the floor in a classroom, smiling as they read a book together. Classroom decorations and another student are visible in the background.

Program structure

Our cyclical lesson design ensures students receive multiple exposures to concepts through a variety of modalities. As they progress through the lessons within a unit, students build and deepen their understanding, increasing their ability to develop and refine complex explanations of the unit’s phenomenon. It’s this proven program structure and lesson design that enables Amplify Science to teach less, but achieve more.

Rather than asking teachers to wade through unnecessary content, we designed our program to address 100 percent of the NGSS and Idaho Standards in fewer days than other programs:

  • In just 120 lessons at grades 6–8
  • In just 66 lessons at grades K–2
  • In just 88 lessons at grades 3–5
A four-step process diagram with icons: spark a real-world problem, explore sources, explain and elaborate, and evaluate claims, all linking to engage with cohesive storylines.

Unit types

Each unit delivers three-dimensional learning experiences and engages students in gathering evidence from a rich collection of sources, while also emphasizing a particular science and engineering practice.

A laptop and two screens display educational content about ecosystems, featuring illustrated plants, animals, and experiments with colorful liquids.
Two young students sit at a classroom table, one holding up a clear cup of water while the other observes closely. Papers and pencils are spread out on the table.

Investigation units

Investigation units focus on the process of strategically developing investigations and gathering data to answer questions. Students are first asked to consider questions about what happens in the natural world and why, and are then involved in designing and conducting investigations that produce data to help answer those questions.

Two children play an educational board game at a table with worksheets, plastic cubes, and small containers of colored items.

Modeling units

Modeling units provide extra support to students engaging in the practice of modeling. Students use physical models, investigate with computer models, and create their own diagrams to help them visualize what might be happening on the nanoscale.

Two children sitting at a table with laptops are talking to each other in a classroom setting, with books and baskets in the background.

Engineering Design units

Engineering design units provide opportunities for students to solve complex problems by applying science principles to the design of functional solutions, and iteratively testing those solutions to determine how well they meet preset criteria.

Several open textbooks and notebooks are spread out on a table as a person writes in one of the notebooks with a pencil.

Argumentation units

Argumentation units are introduced at grade 3 and provide students with regular opportunities to explore and discuss available evidence, time and support to consider how evidence may be leveraged in support of claims, and independence that increases as they mount written arguments in support of their claims.

A person points to a photo in a textbook about coral reefs, with a laptop and notebook open on the desk.

Launch units

Launch units are the first units taught in each year of Amplify Science. The goal of the Launch unit is to introduce students to norms, routines, and practices that will be built on throughout the year, including argumentation, active reading, and using the program’s technology. For example, rather than taking the time to explain the process of active reading in every unit in a given year, it is explained thoroughly in the Launch unit, thereby preparing students to read actively in all subsequent units.

Three students at a classroom table examine a sealed plastic bag with food inside, while one looks surprised; another student stands in the background.

Core units

Core units establish the context of the unit by introducing students to a real-world problem. As students move through lessons in a Core unit, they figure out the unit’s anchoring phenomenon, gain an understanding of the unit’s disciplinary core ideas and science and engineering practices, and make linkages across topics through the crosscutting concepts. Each Core unit culminates with a Science Seminar and final writing activity.

Four students sit at a table using laptops, focused on their screens in a classroom setting with one student in the background.

Engineering Internship units

Engineering Internship units invite students to design solutions for real-world problems as interns for a fictional company called Futura. Students figure out how to help those in need, from tsunami victims in Sri Lanka to premature babies, through the application of engineering practices. In the process, they apply and deepen their learning from Core units.

Idaho Science Standards Alignment

Amplify Science was built from the ground up to fully embrace the instructional shifts outlined in A Framework for K-12 Science Education (2012), the same framework on which Idaho Science Content Standards were founded. Most grade levels’ respective set of Amplify Science units therefore fully address the necessary Idaho Science Content Standards (see correlation). Grade 1 teachers should plan to also use the companion mini-lesson provided below to achieve full standards coverage for their grade.

Grade 1 Companion

Standard: 1-LS-1.3 Use classification supported by evidence to differentiate between living and non-living things.

Recommended placement: Following Lesson 1.1 of the Animal and Plant Defenses unit.

Resources: Classroom Slides

Download Correlation

Science (K-2) Evaluation Form

Science (3-5) Evaluation Form

Science (Middle School Physical Science) Evaluation Form

Science (Middle School Life Science) Evaluation Form

Science Evaluation Form Middle School Earth and Space Science

A boy sits on the floor reading a book to a girl beside him in a classroom setting.
A butterfly flies above potted plants next to a watering can and a caterpillar on a milkweed plant under sunlight in a grassy field.

Needs of Plants and Animals

Domains: Life Science, Earth and Space Science, Engineering Design

Unit type: Investigation

Student role: Scientists

Phenomenon: There are no monarch caterpillars in the Mariposa Grove community garden since vegetables were planted.  

A hand pulls a white string attached to a pegboard with rubber bands and a white ball hanging from the center.

Pushes and Pulls

Domains: Physical Science, Engineering Design

Unit type: Engineering design

Student role: Pinball engineers

Phenomenon: Pinball machines allow people to control the direction and strength of forces on a ball.  

Silhouette of a playground structure and toy train against a blue sky with clouds and two large yellow suns.

Sunlight and Weather

Domains: Earth and Space Science, Life Science, Engineering Design

Unit type: Modeling

Student role: Weather scientists

Phenomenon: Students at Carver Elementary School are too cold during morning recess, while students at Woodland Elementary School are too hot during afternoon recess.  

Illustration of sea turtles swimming among underwater plants, with a shark and another turtle visible in the background.

Animal and Plant Defenses

Domain: Life Science

Unit type: Modeling

Student role: Marine scientists

Phenomenon: Spruce the Sea Turtle lives in an aquarium and will soon be released back into the ocean, where she will survive despite ocean predators.  

A hand holds a flashlight and shines it through a transparent sheet with an image, projecting the image onto a wall in a dark room.

Light and Sound

Domains: Physical Science, Engineering Design

Unit type: Engineering design

Student role: Light and sound engineers

Phenomenon: A puppet show company uses light and sound to depict realistic scenes in puppet shows.  

A split illustration shows a cityscape at night with a crescent moon and stars on the left, and a cityscape during the day with the sun, clouds, and an airplane on the right.

Spinning Earth

Domain: Earth and Space Science

Unit type: Investigation

Student role: Sky scientists

Phenomenon: The sky looks different to Sai and his grandma when they talk on the phone.  

A grey elephant uses its trunk to pick apples from a tree, with a few apples still hanging on the branches and a small sprout growing nearby.

Plant and Animal Relationships

Domains: Life Science, Engineering Design

Unit type: Investigation

Student role: Plant scientists

Phenomenon: No new chalta trees are growing in the fictional Bengal Tiger Reserve in India.  

A hand picks up a red bean from a table scattered with more red beans, spilled white liquid, a cup, and a wooden stick.

Properties of Materials

Domains: Physical Science, Engineering Design

Unit type: Engineering design

Student role: Glue engineers

Phenomenon: Different glue recipes result in glues that have different properties.  

A building labeled "Recreation Center" stands near a cliff edge with a blue flag, surrounded by trees and overlooking a beach and water.

Changing Landforms

Domain: Earth and Space Science

Unit type: Modeling

Student role: Geologists

Phenomenon: The cliff that Oceanside Recreation Center is situated on appears to be receding over time.  

Illustration of a high-speed train traveling on an elevated track with a green landscape and blue sky in the background.

Balancing Forces

Domain: Physical Science

Unit type: Modeling

Student role: Engineers

Phenomenon: The town of Faraday is getting a new train that floats above its tracks.  

A group of wolves stands in the foreground, with a bear, elk, and several birds visible in a grassy, hilly landscape with scattered trees.

Inheritance and Traits

strong>Domain: Life Science

Unit type: Investigation

Student role: Wildlife biologists

Phenomenon: An adopted wolf in Graystone National Park (“Wolf 44”) has some traits that appear similar to one wolf pack in the park and other traits that appear to be similar to a different wolf pack. 

A small bird stands on soil, looking closely at a yellow snail, with green blades of grass on the left and a blue sky background.

Environments and Survival

Domains: Life Science, Engineering Design

Unit type: Engineering design

Student role: Biomimicry engineers

Phenomenon: Over the last 10 years, a population of grove snails has changed: The number of grove snails with yellow shells has decreased, while the number of snails with banded shells has increased.  

An orangutan hangs from a vine in a dense green forest with the sun visible in the background.

Weather and Climate

Domains: Earth and Space Science, Engineering Design

Unit type: Argumentation

Student role: Meteorologists

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

Illustration of city buildings at night with illuminated windows, a full moon, visible stars, and a silhouetted figure in one window.

Energy Conversions

Domains: Physical Science, Earth and Space Science, Engineering Design

Unit type: Engineering design

Student role: System engineers

Phenomenon: The fictional town of Ergstown experiences frequent blackouts.  

A streetlamp illuminates a cricket, which is watched by a gecko. Yellow arrows indicate the flow of light from the lamp to the cricket and then to the gecko’s eye.

Vision and Light

Domain: Physical Science, Life Science, Engineering Design

Unit type: Investigation

Student role: Conservation biologists

Phenomenon: The population of Tokay geckos in a rain forest in the Philippines has decreased since the installation of new highway lights.  

Two dolphins swimming underwater, facing each other against a blue background.

Waves, Energy, and Information

Domains: Physical Science, Life Science, Earth and Space Science, Engineering Design

Unit type: Modeling

Student role: Marine scientists

Phenomenon: Mother dolphins in the fictional Blue Bay National Park seem to be communicating with their calves when they are separated at a distance underwater.

Earth orbits the Sun in space, with dotted blue lines showing the orbital path and a white arrow indicating Earth's rotation direction.

Patterns of Earth and Sky

Domains: Physical Science, Earth and Space Science

Unit type: Investigation

Student role: Astronomers

Phenomenon: An ancient artifact depicts what we see in the sky at different times — the sun during the daytime and different stars during the nighttime — but it is missing a piece.  

Illustration of layered red and brown rocky cliffs beside a flowing blue river under a partly cloudy sky.

Earth’s Features

Domain: Earth and Space Science

Unit type: Argumentation

Student role: Geologists

Phenomenon: A mysterious fossil is discovered in a canyon within the fictional Desert Rocks National Park.  

Red blood cells scattered across a dynamic, abstract red and white background.

Modeling Matter

Domain: Physical Science

Unit type: Modeling

Student role: Food scientists

Phenomenon: Chromatography is a process for separating mixtures. Some solids dissolve in a salad dressing while others do not. Oil and vinegar appear to separate when mixed in a salad dressing.  

Illustration of wind carrying airborne particles over a coastal hill, with arrows indicating the movement up and over the hill toward the sea.

The Earth System

Domains: Earth and Space Science, Physical Science, Engineering Design

Unit type: Engineering Design

Student role: Water resource engineers

Phenomenon: East Ferris, a city on one side of the fictional Ferris Island, is experiencing a water shortage, while West Ferris is not. 

Illustration of a cheetah standing near plants, looking at a sloth hanging from a tree branch, with various foliage and mushrooms in the scene.

Ecosystem Restoration

Domains:Physical Science, Life Science, Earth and Space Science, Engineering Design

Unit type: Argumentation

Student role: Ecologists

Phenomenon: The jaguars, sloths, and cecropia trees in a reforested section of a Costa Rican rain forest are not growing and thriving.  

A rover stands on a rocky, reddish terrain with visible tire tracks leading to it; distant hills are seen under a hazy sky.

Geology on Mars

Domain: Earth and Space Science

Unit type: Launch

Student role: Planetary geologists

Phenomenon: Analyzing data about landforms on Mars can provide evidence that Mars may have once been habitable.  

Illustration of a city skyline at night with a large full moon, a few stars in the sky, and a bridge on the left side.

Earth, Moon, and Sun

Domains: Earth and Space Science, Physical Science

Unit type: Core

Student role: Astronomers

Phenomenon: An astrophotographer can only take pictures of specific features on the Moon at certain times.  

Illustration of a person wearing a red hat and winter coat with fur hood, eyes closed and arms crossed, surrounded by large orange circles.

Thermal Energy

Domain: Physical Science

Unit type: Core

Student role: Thermal scientists

Phenomenon: One of two proposed heating systems for Riverdale School will best heat the school.  

Abstract digital artwork featuring a large yellow sun with blue and orange rays over a colorful landscape with green hills and red horizon.

Ocean, Atmosphere, and Climate

Domains: Earth and Space Science, Physical Science

Unit type: Core

Student role: Climatologists

Phenomenon: During El Niño years, the air temperature in Christchurch, New Zealand is cooler than usual.  

Illustration of clouds above a small town with fields and mountains, showing wind patterns and atmospheric movement in the sky.

Weather Patterns

Domains: Earth and Space Science, Physical Science

Unit type: Core

Student role: Forensic meteorologists

Phenomenon: In recent years, rainstorms in Galetown have been unusually severe.  

An underwater scene with a large whale, several turtles, jellyfish, and fish swimming surrounded by shafts of light.

Populations and Resources

Domains: Life Science, Earth and Space Science

Unit type: Core

Student role: Biologists

Phenomenon: The size of the moon jelly population in Glacier Sea has increased.  

Low-poly illustration of a forest with trees, mushrooms, a rabbit, and a fox catching another animal under a blue sky with mountains and the sun in the background.

Matter and Energy in Ecosystems

Domains: Life Science, Earth and Space Science, Physical Science

Unit type: Core

Student role: Ecologists

Phenomenon: The biodome ecosystem has collapsed.

Illustration of six spiders with different colored bodies and legs arranged in a chart-like formation on a dark background.

Traits and Reproduction

Domain: Life Science

Unit type: Core

Student role: Biomedical students

Phenomenon: Darwin’s bark spider offspring have different silk flexibility traits, even though they have the same parents.  

Abstract digital artwork featuring vibrant colors, geometric shapes, a yellow human silhouette, and various patterns layered together.

Microbiome

Domain: Life Science

Unit type: Launch

Student role: Microbiological researchers

Phenomenon: The presence of 100 trillion microorganisms living on and in the human body may keep the body healthy.  

Illustration of a person receiving an oral examination with a tongue depressor and light, featuring abstract colorful shapes and an eye chart in the background.

Metabolism

Domain: Life Science

Unit type: Core

Student role: Medical researchers

Phenomenon: Elisa, a young patient, feels tired all the time. 

A spacecraft approaches a large modular space station with blue solar panels, orbiting in outer space against a black background.

Force and Motion

Domain: Physical Science

Unit type: Core

Student role: Physicists

Phenomenon: The asteroid sample-collecting pod failed to dock at the space station as planned.

Green geometric background with a hexagonal badge displaying a parachute, ruler, letter A, stacked layers, bandage, and a folded paper icon.

Force and Motion Engineering Internship

Domains: Engineering Design, Physical Science

Unit type: Engineering internship

Student role: Mechanical engineering interns

Phenomenon: Designing emergency supply delivery pods with different structures can maintain the integrity of the supply pods and their contents.  

Two prehistoric aquatic reptiles with long snouts swim near the shore of a tropical landscape with rocks, plants, and an island in the distance.

Plate Motion

Domain: Earth and Space Science

Unit type: Core

Student role: Geologists

Phenomenon: Mesosaurus fossils have been found on continents separated by thousands of kilometers of ocean, even though the Mesosaurus species once lived all together.  

Illustration of a volcanic landscape with mountains, trees, an ocean, and a cross-section showing tectonic plates beneath the surface.

Rock Transformations

Domain: Earth and Space Science

Unit type: Core

Student role: Geologists

Phenomenon: Rock samples from the Great Plains and from the Rocky Mountains — regions hundreds of miles apart — look very different, but have surprisingly similar mineral compositions.  

Four low-poly dinosaurs, three green and one yellow, are walking in a row on grass with rocks and red spots on their bodies under a blue sky.

Natural Selection

Domains: Life Science, Earth and Space Science

Unit type: Core

Student role: Biologists

Phenomenon: The newt population in Oregon State Park has become more poisonous over time.  

Two large tortoises are near a river; one is on the riverbank reaching for leaves on a tree, while the other is on the opposite bank among grass and trees.

Evolutionary History

Domains: Life Science, Earth and Space Science

Unit type: Core

Student role: Paleontologists

Phenomenon: A mystery fossil at the Natural History Museum has similarities with both wolves and whales.    

Two people stand atop rocky terrain littered with electronic devices; inset illustrations show a boot, a person with electronics in a vest, and a radio.

Harnessing Human Energy

Domains: Physical Science, Earth and Space Science, Engineering Design

Unit type: Launch

Student role: Energy scientists

Phenomenon: Rescue workers can use their own human kinetic energy to power the electrical devices they use during rescue missions.  

An orange popsicle melting in four stages from solid to almost fully liquid, set against a plain background.

Phase Change

Domains: Physical Science, Earth and Space Science

Unit type: Core

Student role: Chemists

Phenomenon: A methane lake on Titan no longer appears in images taken by a space probe two years apart.  

Green graphic with icons showing a swaddled baby, a thermometer, layers of blankets, a medical symbol, and a heat source within a hexagonal frame.

Phase Change Engineering Internship

Domains: Engineering Design, Physical Science

Unit type: Engineering internship

Student role: Chemical engineering interns

Phenomenon: Designing portable baby incubators with different combinations of phase change materials can keep babies at a healthy temperature.  

Digital illustration showing red and blue molecule-like circles on a blue background, with a boundary dividing two differently shaded sides.

Chemical Reactions

Domains: Physical Science, Life Science, Earth and Space Science

Unit type: Core

Student role: Forensic chemists

Phenomenon: A mysterious brown substance has been detected in the tap water of Westfield.  

Illustration of people riding a roller coaster on a blue day, with arms raised as the car descends a tall loop against a sky with clouds.

Magnetic Fields

Domain: Physical Science

Unit type: Core

Student role: Physicists

Phenomenon: During a test launch, a spacecraft traveled much faster than expected.  

Illustration of the Earth with arrows representing radiation or energy entering the atmosphere from space over the Asia-Pacific region.

Light Waves

Domains: Physical Science, Life Science, Earth and Space Science

Unit type: Core

Student role: Spectroscopists

Phenomenon: The rate of skin cancer is higher in Australia than in other parts of the world.  

An illustrated polar bear stands on a small piece of floating ice in the ocean, with icebergs and an orange sun in the background.

Earth’s Changing Climate

Domains: Earth and Space Science, Life Science

Unit type: Core

Student role: Climatologists

Phenomenon: The ice on Earth’s surface is melting.

Hexagonal badge with icons including a wrench, building, sun, molecules, construction materials, screwdriver, paint bucket, and a letter T, all on a geometric blue background.

Earth’s Changing Climate Engineering Internship

Domains: Earth and Space Science, Engineering Design

Unit type: Engineering internship

Student role: Civil engineers

Phenomenon: Designing rooftops with different modifications can reduce a city’s impact on climate change.  

Access program

In addition to the grade-level sample boxes that we provided, we’ve also created custom demo accounts just for Idaho reviewers.

To access the digital portion of the program, click the link below, select “Log In with Amplify,” and then refer to the Start here digital access flyer for your personalized login credentials.

Access digital program
A spiral-bound teacher’s guide and a laptop displaying a digital curriculum, both titled “Balancing Forces: Investigating Floating Trains” from Amplify Science.

Tutorial videos

Check out these videos for support on how to navigate the Amplify Science curriculum website, teacher’s guide, materials kits, and more!

Resources

A teacher stands by a table helping four students who are working together on a board game and writing in notebooks in a classroom.

Course structure for K–5

Take a closer look at how the program is organized.

Two students sit at a classroom table working together with notebooks and a workbook, while other students work in the background.

Course structure for 6–8

Take a closer look at how the program is organized.

Two women sit at a desk; one types on a laptop while the other writes in a spiral-bound notebook. Both appear focused and are smiling.

Idaho Science Standards Alignment

See how we customized our instructional sequence to fully support the Idaho Scie…

A collage with Mars landscape art, three kids conducting a tabletop science experiment, an adult's hand holding a jar, and two people hiking in a bright field, illustrated style.

NGSS Earth Science Standards Map

A collage of four images: underwater animals, two students conducting a science experiment, hands building with plastic rods, and a colorful illustration of dancers.

NGSS Life Science Standards Map

A collage showing: a candle flame amid germs, hands measuring a ping pong ball with calipers and a ruler, hands with magnets and a ruler, and a stylized compass over a map of Earth.

NGSS Physical Science Standards Map

Two children sit at a table with laptops, facing each other and talking animatedly, surrounded by books and classroom supplies.

What’s so phenomenal about phenomena?

Learn actionable strategies that will help you implement 3-D teaching and learni…

Illustration of wind carrying particles from a coastal city up a steep, green mountain under a clear blue sky.

Unit phenomena for K–5

Take a closer look at the elementary unit phenomena featured in each grade level…

Illustration of a roller coaster car filled with people raising their arms as it rolls down a steep track against a blue sky with clouds.

Unit phenomena for 6–8

Take a closer look at the middle school unit phenomena featured in each grade le…

A slide with the title “What do you know about aquariums?” next to an underwater photo showing fish and a person swimming. Other science lesson slides are visible above and below.

Classroom Slides for K–5

Classrooms Slides for elementary are now available! These customizable PowerPoin…

A computer screen displays an educational simulation about Earth's energy system, with diagrams and explanatory text about energy entering and exiting the system.

Classroom Slides for 6–8

Classrooms Slides for middle school are coming soon! These customizable PowerPoi…

A computer screen displays an ecosystem selection menu with options for 3 or 6 animal populations, featuring illustrated creatures and labeled icons for each species.

Sims for 4–8

Take a closer look at the digital Simulations included at each grade level.

Two children sit on the floor in a classroom, with one boy reading aloud from a book titled "Gary’s Sand Journal" while a girl listens attentively beside him.

Literacy-rich instruction in K–5

Scientists do not just get messy. They read and write with purpose too. Explore…

A selection of colorful science-themed books and handbooks with illustrated and photographic covers, arranged diagonally on a green background.

Student Books in K–5

Read a summary of each of our award-winning K–5 student books.

A student reads about rock formations from a spiral-bound book while sitting at a table with a laptop; other students work together in the background.

Active reading in 6–8

Learn how we support students in learning how to interact with scientific texts….

Two children wearing safety goggles use plastic spoons to stir substances in clear cups, conducting a science experiment at a table.

Investigations for K–5

Explore the types of investigations that take place in elementary classrooms.

A person wearing gloves looks into a microscope, with laboratory supplies and bottles on a tray beside them, against a plain blue background.

Investigations for 6–8

Explore the types of investigations that take place in middle school classrooms….

Assorted materials including cardboard sheets, tennis balls, rubber bands, hooks, washers, ping pong balls, sticks, tape, string, and screws arranged on a white surface.

Materials Kits for K–5

See what components come in our materials kits!

Assorted science kit components including motors, batteries, propellers, solar panel, rubber bands, wires, plastic containers, metal fasteners, and spools of thread arranged on a white background.

Materials Kits for 6–8

See what components come in our materials kits!

A teacher stands at the front of a classroom, speaking to students seated at desks, with several students raising their hands to participate.

Approaches to assessment in K–5

Learn about our elementary embedded assessments.

Two students sit at desks, writing in notebooks while using laptops in a classroom setting.

Approaches to assessment in 6–8

Learn about our middle school embedded assessments.

Overview Video

The Lawrence Hall of Science

Developed by the science education experts at UC Berkeley’s Lawrence Hall of Science and the digital learning team at Amplify, our program features:

  • phenomena-based approach where students construct a complex understanding of each unit’s anchor phenomenon.
  • A blend of cohesive storylines, hands-on investigations, rich discussions, literacy-rich activities, and digital tools.
  • Carefully crafted units, chapters, lessons, and activities designed to deliver true 3-dimensional learning.
  • An instructional design that supports all learners in accessing all standards.
The logo for The Lawrence Hall of Science, University of California, Berkeley, features blue text on a light background and is recognized by educators using Amplify Science for middle school science programs.

Instructional model

The Amplify Science program is rooted in the proven, research-based pedagogy of Do, Talk, Read, Write, Visualize. Here’s how each element works:

DO

First-hand investigations are an important part of any science classroom, and Amplify Science has students getting hands-on in every unit—from building models of protein molecules to experimenting with electrical systems.

TALK

Student-to-student discourse and full-class discussions are an integral part of the program. Students are provided with numerous opportunities to engage in meaningful oral scientific argumentation, all while fostering a collaborative classroom environment.

READ

Students read scientific articles, focusing their reading activities on searching for evidence related to their investigation and, importantly, on asking and recording questions as they read through fascinating texts on 21st-century topics.

WRITE

Following real-world practices, students write scientific arguments based on evidence they’ve collected, making clear their reasoning about how a given piece of evidence connects to one of several claims.

VISUALIZE

By manipulating digital simulations and using modeling tools to craft visualizations of their thinking— just as real scientists and engineers do—students take their learning far beyond the confines of what they can physically see in the classroom in an exciting and authentic way.

Program structure

Our cyclical lesson design ensures students receive multiple exposures to concepts through a variety of modalities. As they progress through the lessons within a unit, students build and deepen their understanding, increasing their ability to develop and refine complex explanations of the unit’s phenomenon.

It’s this proven program structure and lesson design that enables Amplify Science to address 100% of the NGSS, and support students in mastering the standards.

Graphic showing a research process with four steps: spark intrigue with a real-world problem, explore evidence, explain and elaborate, and evaluate claims, connected in a cycle with arrows.

Unit types

While every unit delivers three-dimensional learning experiences and engages students in gathering evidence from a rich collection of sources, each unit also serves a unique instructional purpose.

In grades 6–8:

  • One unit is a launch unit.
  • Three units are core units.
  • Two units are engineering internships.

Launch units are the first units taught in each year of Amplify Science. The goal of the Launch unit is to introduce students to norms, routines, and practices that will be built on throughout the year, including argumentation, active reading, and using the program’s technology. For example, rather than taking the time to explain the process of active reading in every unit in a given year, it is explained thoroughly in the Launch unit, thereby preparing students to read actively in all subsequent units.

Core units establish the context of the unit by introducing students to a real-world problem. As students move through lessons in a Core unit, they figure out the unit’s anchoring phenomenon, gain an understanding of the unit’s disciplinary core ideas and science and engineering practices, and make linkages across topics through the crosscutting concepts. Each Core unit culminates with a Science Seminar and final writing activity.

Engineering Internship units invite students to design solutions for real-world problems as interns for a fictional company called Futura. Students figure out how to help those in need, from tsunami victims in Sri Lanka to premature babies, through the application of engineering practices. In the process, they apply and deepen their learning from Core units.

Unit sequence

Our lessons follow a structure that is grounded in regular routines while still being flexible enough to allow for a variety of learning experiences.

In fact, our multi-modal instruction offers more opportunities for students to construct meaning, and practice and apply concepts than any other program. What’s more, our modular design means our units can be flexibly arranged to support your instructional goals.

Three columns listing education curriculum topics for grades 6, 7, and 8, focusing on science themes such as microbiomes, mars geology, and harnessing human energy.

Program components

Available digitally and in print, our unit-specific reference guides are chock full of helpful resources, including scientific background knowledge, planning information and resources, color-coded 3-D Statements, detailed lesson plans, tips for delivering instruction, and differentiation strategies.

Amplify Science TG

Hands-on learning is an essential part of Amplify Science, and is integrated into every unit. Students actively participate in science, playing the roles of scientists and engineers as they gather evidence, think critically, solve problems, and develop and defend claims about the world around them. Every unit includes hands-on investigations that are critical to achieving the unit’s learning goals.

A young person wearing gloves looks through a microscope at a table with laboratory supplies, including bottles, slides, and a tray, against a plain blue background.

More hands-on with Flextensions:
Hands-on Flextensions are additional, optional investigations that are included at logical points in the learning progression and give students an opportunity to dig deeper if time permits. These activities offer teachers flexibility to choose to dedicate more time to hands-on learning. Materials referenced in Hands-on Flextension activities will either be included in the unit kit or are easily sourced. Supporting resources such as student worksheets will be included as downloadable PDF files.

Our kits include enough materials to support 200 student uses. In other words, teachers can easily support all five periods and small groups of 4-5 students each. Plus, our unit-specific kits mean teachers just grab the tub they need and then put it all back with ease.

Amplify Science California supports 3-D learning with more materials than any other program.

Our digital Simulations and Practice Tools are powerful resources for exploration, data collection, and student collaboration. They allow students the ability to explore scientific concepts that might otherwise be invisible or impossible to see with the naked eye.

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

In grades 6–8, one copy of the Student Investigation Notebook is included in each unit’s materials kit for use as a blackline master. Each notebook is also available as a downloadable PDF on the Unit Guide page of the digital Teacher’s Guide.

Two booklets titled "El clima cambiante de la Tierra: la desaparición del hielo" and "Earth’s Changing Climate: Vanishing Ice" with landscape illustrations on the covers.

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.

A laptop displays a PowerPoint presentation in presenter view, with slides about observing objects in plastic containers and related sensory instructions.

Explore your print samples

With your Amplify Science print samples, you’ll find unit-specific Teacher’s References Guides and Student Investigation Notebooks for each grade level.

A note about the Teacher’s Reference Guides:

It’s important that your committee sees the full breadth and depth of our instruction. For that reason, we provided a copy of each of our unit-specific Teacher Reference Guides.

Rest assured that teachers do not use these robust reference guides for day-to-day teaching. For that, we have a hands-free TG!

A laptop screen shows an energy simulation, with surrounding text and diagrams explaining the Earth's system and energy flow.
  • Teacher Reference Guide: Unlike a typical TG that requires a series of supplemental books to support it, our encyclopedic reference guide is chock-full of everything a teacher needs to fully implement our program and the NGSS.
  • Ready-to-Teach Lesson Slides: For daily instruction, teachers need their hands free. That’s why we created ready-to-teach lesson slides for every single lesson. What’s more, they are editable and include suggested teacher talk and point-of-use differentiation and other instructional tips. Click to learn more.

A note about the Materials Kits:

Hands-on learning is at the heart of Amplify Science, and is integrated into every unit. In order to make hands-on learning more manageable for busy teachers, Amplify Science materials are organized into unit-specific kits.

Stacked storage bins with labels, arranged neatly; caption notes they are a sample and may not reflect actual quantities or sizes.

Our unit-specific kits:

  • Include more materials — We give teachers enough materials to support 200 student uses.
  • Are more manageable — Unlike other programs that require large groups of students to share limited sets of materials, our kits include enough to support small groups of 4–5 students.
  • Include supportive videos — Each hands-on activity provides clear instructions for the teacher, with more complex activities supported by video demonstrations and illustrations.

What comes in each grade level kit? Click the links below to see the grade-specific lists of all materials included in each kit.

Access your digital samples

Explore as a teacher

Follow these instructions to explore the Amplify Science digital platform as a teacher.

  • Click the Access Amplify Science Platform button below and bookmark it.
  • Select Log in with Amplify.
  • Enter the username: t1.jeffersoncounty@demo.tryamplify.net
  • Enter the password: Amplify1-jeffersoncounty
  • Click the Science icon.
  • Click on the Program Menu in the top center of the screen and select any grade.
  • Select any unit.
Access Amplify Science Platform

To help familiarize yourself with navigating the digital platform,watch the below navigational video.

Explore as a student

Follow these instructions to explore the Amplify Science digital platform as a student.

  • Click the Access Amplify Science Platform button below and bookmark it.
  • Select Log in with Amplify.
  • Enter the username: s1.jeffersoncounty@demo.tryamplify.net
  • Enter the password: Amplify1-jeffersoncounty
  • Click the Science icon.
  • Click on the Grade Menu in the top center of the screen and select any grade.
  • Select any unit.
Access Amplify Science Platform

Resources to support your review

S3-04: Using AI and ChatGPT in the science classroom

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

In the latest episode of the Science Connections podcast, we explore AI in education and its impact on students. Listen as I sit down with teachers Donnie Piercey and Jennifer Roberts to discuss ChatGPT and how we can use it to build science and literacy skills in K–12 classrooms while preparing students for the real world.

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

Jennifer Roberts (00:00:00):

If a kid graduates from school without knowing that AI exists, they’re not gonna be prepared for what they face out in the world.

Eric Cross (00:00:07):

Welcome to Science Connections. I’m your host, Eric Cross.

Eric Cross (00:00:12):

This season of the podcast, we’re making the case for everyone’s favorite underdog, science. Recently we’ve been highlighting the magic that can come from integrating science and literacy. So if you haven’t checked out those recent episodes, definitely go back in your feed after you’re done with this one. This time around, we’re going to deep dive into what artificial intelligence means for literacy instruction, and how science can be a force for good, in responsibly exposing students to AI. To help me out, I’m joined by two extremely accomplished educators. Jen Roberts, a veteran high-school English teacher from San Diego, who among many things runs the website LitAndTech.com. And I’m also joined by fifth-grade teacher Donnie Piercey. In addition to being Kentucky’s 2021 Teacher of the Year, Donnie also has an upcoming book about bringing AI into the classroom. Whether you’ve never heard of ChatGPT or whether you’re already using it every day, I think you’ll find this a valuable discussion about the intersection of science, English, and technology. Here’s Jen and Donnie.

Eric Cross (00:01:17):

So first off, welcome to the show. It’s good to see you all. What I wanna do is kind of start off by introducing both of you. And so we’ll just go K–12. So <laugh>, Donnie.

Jennifer Roberts (00:01:30):

Donnie goes first.

Eric Cross (00:01:31):

Donnie’s gonna go first. Donnie out in Kentucky. Just a little background. What do you teach; how long you’ve been in the classroom; and what are you having fun with right now?

Donnie Piercey (00:01:38):

Yeah, so my name is Donnie Piercey. I’m a fifth-grade teacher from Kentucky. Live and teach right here in Lexington, Kentucky, right in the center of the state. I’m the 2021 Kentucky Teacher of the Year. But I’ve been teaching elementary school for the past … I think this is year 16 or 17. It’s long enough where I’ve lost count, and I can’t even count on fingers anymore. My friends like to joke that I’ve taught long enough where now I can count down. You know, it’s like, “All right, only so many more years left.” But yeah, teach all subjects. Science definitely is one of the subjects that I don’t just try to squeeze into my day, but make sure that … it’s not even a devoted subject, but one that I definitely try to — don’t just have that set time, but also try to do some cross-curricular stuff with it. So definitely the rise of AI in these past few months, which feels like years by this point, has definitely played quite the role, in not just changing the way that I’ve been teaching science, but really all my subjects. So, excited to chat with y’all about it.

Eric Cross (00:02:47):

Nice. I’m excited that you’re here. And Jen?

Jennifer Roberts (00:02:51):

Hi, I’m Jen Roberts. I teach ninth-grade English at Point Loma High School, and that’s where I usually stop when I introduce myself. But for your sake—

Eric Cross (00:03:00):

I will keep introducing you if you stop there. <laugh>

Jennifer Roberts (00:03:04):

I am nationally board-certified in English Language Arts for early adolescence. I am the co-author of a book called Power Up: Making the Shift to 1:1 Teaching and Learning, from Stenhouse, with my fabulous co-author Diana Neebe. Shout out to Diana. I blog at LitAndTech.com about teaching and technology and literacy and the intersection of those things. And I’m looking forward to talking about how AI is showing up in my classroom and the fun things I’m doing with it.

Donnie Piercey (00:03:31):

And one of us is actually secretly a robot, and you have to guess which one.

Jennifer Roberts (00:03:35):

Have to guess which one. Yes. <laugh>

Eric Cross (00:03:37):

That would be super-meta. And you were the CUE — Computer-Using Educator — outstanding teacher or educator? Whatever. Either one. Of the year.

Jennifer Roberts (00:03:45):

I was the CUE ’22 Outstanding Educator. Yes. And I’ve won a few other things as well.

Eric Cross (00:03:53):

The gaming backpack.

Jennifer Roberts (00:03:54):

I’ve won a gaming backpack recently! Yes. I once won an iPad in a Twitter chat.

Eric Cross (00:03:58):

What?

Donnie Piercey (00:03:58):

What’s a gaming backpack? Hold on. We need to talk about that.

Jennifer Roberts (00:04:01):

We will talk about that. <laugh> And then, I was once a finalist for county Teacher of the Year. That’s as close as I got to Donnie. Donnie was the Kentucky Teacher of the Year. He got to go to the White House and stuff. That was exciting.

Donnie Piercey (00:04:13):

<laugh> I mean, to be fair, there’s only three million people in Kentucky, and about what, 50 million people that live in California? <Laugh> So odds are definitely stacked in my favor, I think.

Jennifer Roberts (00:04:23):

So you’re saying we’re even there? Is that, is that what you’re going for?

Donnie Piercey (00:04:25):

Yeah, evens out. Evens out.

Eric Cross (00:04:27):

So I’ve been looking forward to talking to you both for a while now, and talking about artificial intelligence. It’s like the big thing. And both of you, at different ends of the spectrum and in my life, have contributed to this. Donnie, you’ve been sharing so much great information online about how you’re using AI in elementary. Jen, you are the reason I got into education technology years ago, right when I was becoming a teacher. And so being able to talk with you both about it excites me a lot. So first off, for the listeners who may not have any experience with it — and there’s still a lot of people out there who have not been exposed to it, haven’t got their feet wet with it yet — I’m hoping we could start off maybe with an explanation of … we could do AI, ChatGPT, I know that’s the big one. But simply explaining what it is, just for the new person. And whoever wants to start off can tell us about it. Or maybe we’ll start … we’ll, let’s actually, let’s do this: Let’s continue going like K–12? So Donnie, maybe you could … what’s your pitch to the new person of, “Hey, this is what it is”?

Donnie Piercey (00:05:31):

All right. So, AI, artificial intelligence, probably the way that most people are exposed to it, at least since November when it launched, is through ChatGPT. Where if you Google it, you know it’s made by a company called OpenAI. The best way to describe what it is … when you go there for the first time, make an account, it’s free. You have like a little search window, looks like a Google search bar. And instead of searching for information, you can ask it to create stuff for you. So for example, like on Google search, you might type in a question like, “Who was the 19th president of the United States?” Where on ChatGPT, instead of just searching for information, it creates stuff for you. So you could say, you could ask it to, “Hey, write a poem about the 19th president of the United States.” Or, “Write a short little essay comparing, I don’t know, Frederick Douglass to Martin Luther King Jr.” And it would do that for you. You know, that’s most people’s first exposure to AI, at least in these past few months. Instead of … you know, it’s artificial intelligence, but it’s not just chatbots. There’s lots of other AI that exist out there.

Jennifer Roberts (00:06:47):

And I think that’s the thing: that people don’t realize how much AI is already in their lives.

Donnie Piercey (00:06:51):

For sure. Yeah.

Jennifer Roberts (00:06:52):

You know, they just haven’t seen … the term that I see being used a lot now is “generative AI.” AI that can produce something. It can produce writing, it can produce art, it can produce a script, it can produce a character. But the AI that has been helping you pick what to watch next on Netflix and the AI that’s helping Google help you get where you wanna go on Google Maps faster, those are forms of artificial intelligence as well.

Donnie Piercey (00:07:21):

Yeah. I mean, even those, when you get that that message in Gmail, and instead of having to type out that response that says, “Yeah, that sounds great,” you can just click the little button that says, “Yeah, that sounds great.” I mean, that’s been in Gmail for years, but that’s artificial intelligence too.

Eric Cross (00:07:39):

Absolutely. So why is it important, do you think, for educators to, to be familiar with it? Like, why are we all so excited about it?

Jennifer Roberts (00:07:47):

So, educators need to know what kids are into, and kids are obviously into ChatGPT. And anyone who’s an educator right now has probably already had something cross their desk — or more likely their computer screen — that was written by AI and passed off as a student’s own work. And that is, of course, the great fear among teachers everywhere, that this is what kids are just gonna do these days and they won’t be able to catch it and children won’t be doing their own work and this and this. But I think the big reason teachers need to know what’s going on is because teachers need to be futurists. Our clientele will live in the future. We teach kids, kids will become adults, adults will live in the world. And so if we’re not thinking about and trying to predict on some level what’s gonna happen 5, 10, 15 years from now … we might be wrong, but what if we’re right?

Jennifer Roberts (00:08:38):

And if we’re not at least trying to think about what is their future world gonna look like, then we’re not serving our students well. I did a whole night talk on that. So I think ChatGPT is part of that. I teach seniors. I had this moment of realization I felt a few months ago. I’m like, “This is gonna be the world they graduate into. They need to know what this is before they leave me.” If I don’t teach them how to use this well, and not the way they’re using it — which is to copy and paste the teacher’s assignment and drop it into ChatGPT and take whatever it spits out and turning that in without even looking at it — if I don’t teach ’em how to use it critically, if I don’t teach them how to write effective prompts, if I don’t teach them how to use the AI as a tool, as a collaborator, then they’re gonna graduate into a world where they lose out to people who do know how to do that. And I think the advantage goes to kids who have access and knowledge of what’s in front of them and what’s available, and can use all of the tools at their disposal. Because when you’re writing in school and you write with a collaborator, that could be considered cheating. But when you do that out in the adult world, that’s considered doing a good job. <Laugh> Being a team player. <Laugh> You know, adults don’t work alone for the most part. And adults are expected to churn out beautiful, perfect content no matter how they got there. So if I’m not teaching my kids how to use this, they’re not being ready. They’re not gonna be ready to be the adults that I want them to be.

Donnie Piercey (00:10:07):

A hundred percent agree. And I also believe … as you know, I teach elementary school. I also don’t think anybody is saying that on the first day of kindergarten, you hand a kid a Chromebook and load up an AI chatbot or ChatGPT and say, Hey, this thing’s gonna do all your work for you for the next 12 years; just coast through life. You don’t have to think creatively. You don’t have to learn how to develop a paragraph or learn how to write a speech or develop an idea. Like, I don’t think anybody’s saying that, because as an elementary school teacher, there’s many days when I’m like, “Y’all, we’re just putting the Chromebooks away today and we’re just gonna go old-school. We’re just gonna maybe just jot down five quick ideas and stand up and present those ideas to the class.”

Donnie Piercey (00:10:54):

Because while AI definitely will, like you were saying, Jen, play a significant role in the lives of our students who are, not just graduating, but the 10- and 11-year-olds in my classroom this year. A significant role in their lives. It’s also really important to recognize that we’re not saying that this means that “Hey, kids don’t have to work anymore.” They still have to put forth that effort. There’s still — one of the ways that you become a good writer is by trial and error. And sometimes that trial and error comes through talking to a teacher or talking like you were saying to a peer or collaborating with a peer and saying to them, “Well, this sentence here, this paragraph here, really doesn’t make sense.” And I do believe one of the ways — especially as AI starts to become more fine-tuned and starts to be embedded more and more in tools like Google Docs and Microsoft Word — is it’s almost going to be a tutor to students.

Donnie Piercey (00:11:56):

Mm-hmm. <affirmative> Where I could very easily see in a few years, or maybe a few months, who knows what Google or any of these other big companies has rolling out, where a student could highlight a paragraph that they wrote simply, and then say, “Hey, proofread this for me,” or “Check for coherence.” Or even just ask a simple question: “Does this paragraph make sense?” Because you can already do that. You can copy a paragraph over into a chatbot and say, “Hey, does this make sense?” You know, “Rate my idea from one to 10,” and it’ll do that for ’em.

Jennifer Roberts (00:12:26):

We did that last week <laugh>.

Donnie Piercey (00:12:28):

Yeah. Right. I mean, that’s the thing. That technology exists now. It’s just not totally embedded yet. But based on what I’ve read and what I’ve seen, that’s gonna happen sooner rather than later. And it’s really, really important that we teach our students that, “No, you’re not just gonna use this, this tool to cheat, but you can use this tool to help you become a more creative student.”

Jennifer Roberts (00:12:50):

This is the use case in my classroom. Can I talk about that? You ready for that?

Eric Cross (00:12:53):

Please.

Jennifer Roberts (00:12:54):

OK.

Eric Cross (00:12:54):

Please.

Jennifer Roberts (00:12:55):

So my ninth graders are writing a comparative analysis essay, where I took them to the student art gallery and I made them pick two pieces of completely unknown student art and take notes on it, so they could go back and write this essay. And as soon as we got back to class, I said, can ChatGPT write this for you? And they all kind of froze ’cause I didn’t tell them what ChatGPT was. And they weren’t sure if they were allowed to know or not. And finally one of them kind of bravely raised his hand and said, “No.” And I said, “Why not?” And he said, “Well, the AI hasn’t seen the art. How can it write an essay about art when the art is completely original that we just went and looked at?” I said, “It’s almost like I planned it that way, isn’t it?” And they laughed nervously. And then I said, “Does that mean it can’t help us with this assignment?” And they said, “Well, no — of course it can’t help us, because it has not seen the art.” And I said, “Well. …” And I open ChatGPT, and I typed in what they were trying to do: “I need to write a comparative analysis essay comparing two pieces of student art on these reasons. And I need to choose which one did it better, basically. Can you help me with an outline?” and ChatGPT produced a lovely outline. And I looked at that with my students and we looked at it together and I said, “This is what it gave us. Would this be helpful to you?” And they’re like, “Yeah, that would be helpful to us.” So we — to be clear here, I was the only one using ChatGPT in the room. They were not actually using it. We were using it together. I copied and pasted the outline that it gave us and put it in their learning management system where they could access it so they could use the outline that the robot provided, and then they could use that to make their own writing better. So then I let them write for a little while, and, after they’d written for a little while, I said, “Does anybody wanna let me share your first paragraph with ChatGPT and see what it thinks of how you’re doing?” And a brave student raised his hand and we took his paragraph and we put it in ChatGPT, and it spit back advice. We said, “This is what I have so far for my first paragraph. Do you have any advice for me?” And we gave it the writing, and the first piece of advice it gave back was very generic, you know, “Add a hook,” you know, like kind of thing. But after that, it started to get more specific about things he was actually doing in his writing. And it started to give him some feedback. And we looked at that together as a class. And I said, “Does any of that feedback help you?” And he said, “Oh yeah, absolutely. I’m gonna go add some revisions to my paragraph.” And other students did too. They looked at the feedback he got and used that to improve their writing. And so everybody went and revised. And I said, “Look, if you take what the robot gives you and you copy and paste it, and you turn it in as your own work, it’s gonna get flagged for plagiarism. And that’s not gonna go well. But if it gives you writing advice the same way I would give you writing advice, and you decide that advice is good, and you take that advice and you incorporate it into your own writing yourself, then the robot’s making you better, but you’re still the one doing your own writing.” And the writing they turned in from that assignment was, was better. It wasn’t written by ChatGPT; it was still about the student art that they found in the gallery. But I showed them a path. Like, it can help you with an outline, it can help you with feedback. Right? These are fair ways to use it that’s gonna make you better. And they really liked that. They really liked — no one had shown them that before. The idea that you don’t just take the teacher’s prompt and give it to it … like, these are new uses to students and worked well.

Eric Cross (00:16:17):

So right now, you both just laid out these ways that you’re using it. And I do this with people that I’m trying to introduce to ChatGPT or AI. ‘Cause I get excited. Anyone could write a 500-word persuasive essay on the use of color in The Great Gatsby or The Outsiders, and they can get something back within seconds. But for a lot of educators, it might feel like the sky is falling.

Donnie Piercey (00:16:43):

Oh, understandably! Understandably. I mean, that totally makes sense.

Eric Cross (00:16:49):

What would you say to them? Donnie, go ahead.

Donnie Piercey (00:16:51):

Yeah. Well, I feel like every teacher kind of goes through the same experience when they see like a generative chatbot. I mean, all these major companies are gonna start incorporating AI, the generative AI piece. And a lot of times, when they see it for the first time, two things. First they’ll say “Oh, but I’ll know that that’s not my students’ writing.” Which, frankly, I think is a good thing, because that tells me that the teachers know their students’ writing. They’ve seen them write in person. They’ve conferenced with them one-on-one. And if a student were to turn something in to me, who I know might be a struggling writer, maybe it’s not their strength, and all of a sudden they’re turning in this10-page dissertation-worthy thesis written at a PhD level, I’m like, “All right, man, you’re nine. Can we talk about where this came from?” <laugh> But I also don’t think that at like the heart, I don’t feel like kids want to cheat. I really don’t. I feel like sometimes like kids are in a situation where they’re like, “OK, I’ve got nothing left. I gotta get this assignment done.” And when those kind of things happen, that’s when we as teachers, we have those one-on-one conversations. Even when I showed my students ChatGPT and even some of the AI image-generating stuff for the first time, and I talked to them about, “What do y’all think about this?” Because, you know, they’re under 13. In my district, ChatGPT is blocked for students. Staff, we have access to it. And that’s just because one, it’s so new, and at the same time, we need to figure out, “What’s the best way they can go about using this tool?” But when we were talking about it as a class, you know, I didn’t want to ignore the elephant in the room. So I asked them, I said, “Hey, do you feel like this is something that you all would use to. …” I mean, I used the word. I said “cheat.” And to be honest, the majority of the students in my class, they were taken aback. They’re like, “What? You think we just would cheat all the time?” Right? <Laugh> And I’m like, “Oh, well good. I’m glad to know that integrity is still alive and well.” But yeah, that’s definitely my thoughts on it, as far as not only the student integrity piece — I think that that’s the big thing that you need to just bring up with your students. Because again, I like to think that I’ve seen my students write enough that if they were going to turn something in that wasn’t their voice, or it didn’t sound like them, like I could have that conversation. And don’t be surprised, too, if in the next … I don’t know, one month to a year, there’s lots of AI detectors that exist. A lot of them are these like third-party things. You can go ahead, but I would not be surprised if in the next year or so, like you start to see those AI detectors be built into Google Docs, into Microsoft Word, into even Canva. And honestly, it’s almost like a fail-safe button for teachers, that we could say “All right, this is telling me that this is 99% probably written by AI.” So you can have that conversation with a student that way.

Jennifer Roberts (00:20:03):

I mean, if you’re worried about it, Formative, right now, will even tell you if something is copy-and-pasted into the boxes that they give you for students to write in. I find that kids who cheat are desperate, you know. Especially at the high school level. They’re panic mode. And, and usually their panic comes from, “I have no idea how to even start this assignment.” And so part of what I wanna use ChatGPT for is to lower that barrier for them. Like, you’ve got an assignment, you don’t know where to start. Tell the robot, tell ChatGPT, about the assignment and ask it for a list of steps. You know, ask it for an outline. Ask it for a time management plan. I see so much tremendous potential for this to help many of my students with IEPs who have executive functioning issues.

Donnie Piercey (00:20:49):

Oh, a hundred percent, right?

Jennifer Roberts (00:20:51):

Yes, a hundred percent. This can be their personal assistant who, you know, instead of me sitting with them one-on-one and saying, you know, “This is the task you need to do, let’s break it down into these six discrete chunks,” the artificial intelligence can do that for them. And it can do that for teachers too. <laugh>

Donnie Piercey (00:21:09):

Jen, I was just thinking about, how long until we see like the phrase artificial intelligence written onto a student’s IEP? I could see that happening very, very soon.

Jennifer Roberts (00:21:20):

Right? They should be able to use that. And then, also, of course, all of its amazing beneficials for teachers. I had to completely rewrite a unit of my curriculum. I knew what I wanted to do. I had some ideas of things I wanted to put in there. And I resorted to, I went to EducationCopilot.com and typed in my stuff that I had: You know, what standards I wanted to cover, what outcomes I was hoping for mm-hmm. <affirmative>. And it generated an eight-week unit for me. And I actually told it then to go back and do it as a 12-week unit so that I’d have more stuff in there to go and cherry-pick to decide what I really wanted to do. But it gave me ideas. It gave me places to start. It saved me an hour of just brainstorming. And I don’t think that was cheating. I still got to go in and decide which ideas were valid. And I still got to … you know, I mean, I’m a teacher. Can I get accused of cheating? I don’t think that’s a thing. It’s—

Eric Cross (00:22:18):

That’s collaborating! It’s collaborating!

Donnie Piercey (00:22:20):

Collaborating! It’s a feature! It’s a feature.

Jennifer Roberts (00:22:22):

It’s Tony Stark talking to Jarvis. You know, they’re figuring it out together.

Donnie Piercey (00:22:26):

Oh, when you use the AI, Jennifer, do you call yours Jarvis? In my class we call him Jeeves. ‘Cause remember Ask Jeeves?

Jennifer Roberts (00:22:33):

I think Eric calls it Jarvis.

Eric Cross (00:22:35):

Yeah. Jarvis is gonna be the AI’s name when, when I can get that fully functioning. There are some things that you had said, I just wanna circle back on. Donnie, Jen — so what I heard was like, best intentions. The part you said about integrity and students wanting to cheat … even the mindset that we go in assuming our students, what they would want to do and assuming best intentions, really kind of frames how you look at this kind of technology. And then Jen, you kind of brought up why students cheat, and realizing that either they don’t feel equipped, or maybe it’s time management, or something else. But most people — and I believe this as an educator — most students want to learn, and they want to be able to perform and achieve. And when they cheat, it’s because they didn’t feel like they could, for whatever reason. Whether it’s it’s outside factors, whether it’s something internal, motivation, whatever it is.

Jennifer Roberts (00:23:24):

Or they were very disconnected and just didn’t care.

Eric Cross (00:23:27):

Sure.

Jennifer Roberts (00:23:27):

This is just busy work the teacher’s giving me, so I’m gonna give it very little of my time and energy. But I think, yeah, it can be that. But if the kid cares about it, if they wanna learn, they wanna learn, you know?

Eric Cross (00:23:40):

Right.

Jennifer Roberts (00:23:40):

This is the day of the internet. Any kid can learn anything they really want to learn. And we see that all the time in our classes. The kid who has zero interest in what I’m teaching in English, but he is an expert coder, and that’s what he wants to spend his time learning. He’s like, “Can I read this C++ book as my independent reading book?” And I’m like, “You know, actually, you can. Go ahead.” <Laugh>

Eric Cross (00:24:01):

Yeah. And for both of you, saying that this makes content more accessible … and I think Donnie, or Jen, you said something about IEPs. I actually put in having it write an IEP to see what would happen. I gave it a prompt for a student’s ability level and I asked it to create a plan. And then I asked it to create a rationale. And it did! And it was good! I went through and vetted it. And right now … you know, a lot of it is funny, ’cause the conversation I’m having with different teachers is kind of like the Wikipedia one. Remember when Wikipedia first got out and everyone was like trying to discourage everybody from using it, because, well, it could be changed by anybody? And now everyone’s like, “Oh, check Wikipedia, and then steal the sources, ’cause they’re already done for you.” Like, the mindset has shifted since then. And I was talking to someone and they said, “Well. …” And I said, “We can use AI, it could be a tutor, these other things. …” And they said, “Yeah, but what happens?” And then insert apocalyptic scenario. Like, what happens if you don’t have access to wifi? And it reminded me of, for some reason, cooking classes. So in the 1700s you probably had to be able to farm to be able to generate your food. Right? Like, you had to get it from somewhere. But if you take a culinary class now, you just go to the grocery store. And someone might say, “Well, but you should know how to farm, ’cause what if there was this worldwide apocalypse and nobody could go to the grocery stores?” <Laugh> And you’re like, “Well, balance of probability though.” You know, it’s like we’ve been really been living in these iterations of life, and I think this next step for some folks … like, we don’t even realize, even like something like bank statements, right? So many folks are paperless. And there’s always a what-if scenario. What if you need it and the internet goes down. But we get so used to to to technology advancing and making our lives different. This kind of seems like that next iteration. And I wanna ask you this question: Are we looking at like the next calculator? The next internet, with this tech? Or do you think it’s too early to say?

Donnie Piercey (00:26:01):

Well, I’ve seen a lot of people compare ChatGPT to a calculator. I’ve seen that pop up on social media. There’s, “Oh well, no, this is like when the calculator was invented. Everyone was up in arms about how ‘that’s not what math students should do.’ Math should be pencil and paper, math should be this.’” However, you can give a kid a calculator and you can give ’em a word problem and they can punch in all the numbers, but they could do the wrong operation or they could put the decimal point in the wrong place, ’cause the student is still the one who’s controlling what’s on the calculator. Where with AI, all you gotta do is just copy it and then paste it into the bot and it’ll spit out whatever the question asked it for. Whether it was, you know, a 500-word rationale or proof for something in geometry, or if it’s analyzing data on a chart, it’ll do all that.

Jennifer Roberts (00:27:00):

Yes. But it’s not that magical. It’s back to what Eric did with the IEP. He put in a prompt and then he knew enough to ask for a rationale and then he knew enough about IEPs to critically read the results he got and make sure they actually worked for what he needed. He had to know all that. He was an expert using it to do an expert thing. My husband’s a computer scientist; he got ChatGPT to help him write an app, and it was a new programming language to him, and he could put in the data and he could ask for things that I would’ve never thought to ask for. But because he knows the language of computer science, he knew what to ask for. And when it gave him results that were bad, he could see that, and he could say, “Yes, but do it again, but without this,” or “make this part more efficient.” He, again, knew what to ask for. So I think the generative AI is, as a partner with humans, a powerful thing. But if the human doesn’t know what they’re doing, yeah. You’re still not gonna get great results.

Donnie Piercey (00:28:03):

<laugh> And I think that’s why I’m coming at this from the elementary school perspective, right? Because in K–5 students are still learning, like, “Hey, where does the decimal point go?” They’re still learning, you know, if you’re dividing by a two-digit number, where does the first digit go, if you go in the old long-division algorithm? And so they’re still acquiring that base-level knowledge that … I don’t know, maybe this is similar to in Jurassic Park when Jeff Goldblum says, “It didn’t take any knowledge to attain,” you know, “they stood on the shoulders of geniuses,” that whole thing. Like they had to acquire the knowledge for themselves, was his whole point. And so that’s why I don’t think it’s exactly the same as the calculator. It is definitely going to change things, in a similar way that the calculator did. But to me it’s just a whole new animal. And I don’t know if it’s going to be like the next internet, Eric — if you’re gonna get little devices that have AI built into it, like a Star Wars kind of thing, like a droid or something that follows you around — all that would be kind of cool, not gonna lie. But whether it’s something that you’ll access through the internet, something that’s built into your TV, that part I don’t know. But I do know that there’s a reason why all of these apps and all these companies are investing so much — not just energy, but time and money into it. Because they’re recognizing. “OK, this really has the potential to change things.” But if used well, and used safely, to change people’s lives for the better.

Eric Cross (00:29:41):

So I definitely hear that you both agree with the statement that if AI ChatGPT was used in the classroom, it could be a force for good. And literacy development. And I wanna shift gears a bit and then come back to the AI. So with that said — and we’re gonna get into some best practices in a minute — in Science Connections right now in this season, we’re making the case for how science can do more in classrooms and in schools. And so I’m I’m curious about what both of you think about the role in science fostering a better future when it comes to AI and education. And this season we’re really talking a lot about literacy. You know, in schools, so often it’s taught in a siloed way. And Donnie, you’re doing multi-subject. Jen, you’re single-subject: English. And we’ve really been trying to make this case for how science can actually support literacy, and these skills that students are trying to develop. So we’re going a little old-school, kind of diving into your content specialty, but maybe even pre-AI, or maybe AI has a component in this. But Don, maybe we’ll start with you. How has science been a way that has been helpful for your own literacy instruction? I know you do a lot of science, because I see your Google Earth stuff and the thing you did with the solar systems back in the day. And I think —.

Donnie Piercey (00:30:54):

Oh my gosh! You remember my <laugh> … wow.

Eric Cross (00:30:58):

That was amazing!

Donnie Piercey (00:31:00):

We haven’t done that since the pandemic. But I had my students go out, and using Google Earth, we built a scale model. Each of the students partnered up and they planned out on Google Earth a scale model of the solar system. They picked an object from around their house and we talked about like, “Don’t pick something bigger than a beach ball, or else, you know, your Neptune’s gonna end up like 10 miles away.” But you know, they just picked like a small ball, like a basketball, soccer ball, something like that. Or football, for international friends. And then we calculated the size of every other planet. And then on Google Earth, using their front lawn as where the sun was, then we went and we calculated where other planets would be, and then we actually drove to those locations and like held up the objects that would represent Neptune, Jupiter, Saturn, and all that. But it was a lot of fun.

Eric Cross (00:31:59):

And is that still accessible? ‘Cause I know you have some websites that you put resources out there.

Donnie Piercey (00:32:03):

Yeah. Yeah, I can … I wanna say on my Resources page — Resources.MrPiercey.com — I’ve got a link on there to a couple of student examples that I can share. And if not, when we get off this call, I’m gonna go on and put them on there <laugh> so people can find it. I’ll even throw on there just the assignment itself. So if you wanted to copy that and do that with your students, you could.

Eric Cross (00:32:27):

Donnie, the reason why I brought that up is because I saw that you had posted that or shared it a long time ago, and I just thought it was the coolest thing that you could totally do with middle-school students or high-school students. Jen, when I became a teacher, you said, “We’re all teachers of literacy.”

Jennifer Roberts (00:32:43):

<laugh> Yeah. I think we forgot to tell them that I was one of your professors.

Eric Cross (00:32:47):

Yes. <Jennifer laughs> One of the people who’ve definitely influenced and shaped my teaching. And that statement has never left my mind: that we’re all teachers of literacy. And I want to ask you, at the high-school level, how can science educators, or how can science — how have you seen it, or how does it, support literacy, when it’s done right?

Jennifer Roberts (00:33:09):

Like I said, I think we’re all teachers of literacy, but I think literacy is bigger than just reading and writing. I don’t think someone is literate if they can’t talk somewhat knowledgeably about what’s happening with climate change. I don’t think someone’s literate if they don’t know what’s going on in the world. And I think so much of what’s going on in the world has to do with science. We’re doing that all the time. If I could teach English just by giving kids articles about science, things to read, that would make my day. Right? We would never read another piece of fiction again. It would all be, you know, what’s happening to the ice sheet in Greenland. My students thrive on reading non-fiction. And then whenever that non-fiction touches on science is even more interesting. And whenever I can get them writing about data, particularly their own data that they collected, I think that’s building those science literacy skills as well. So I think science and English blend together very, very well. I think the literacy aspects of that are fantastic. There are more subject-specific vocabulary words, advanced vocabulary words, in science than any other discipline. And I don’t see why those shouldn’t come up in English as well. You know, my seniors will do a unit at the end of the year on the new space race. Unless I replace it with a unit about generative AI, which I’m seriously considering doing, ’cause I think they really need to learn about bias in AI algorithms and things like that. And I would like to have them read a whole bunch about that stuff. And I wanna give them the open letter that all those CEOs signed that said that AI research should slow down, and make them part of that live conversation about what’s happening in that field. So science comes into that. You know, when we read Into the Wild, we start talking about a whole bunch of scientific concepts. And when it rains in Southern California, we pull up weather maps and look at radar and talk about that and how that works.

Donnie Piercey (00:34:59):

That’s like once every 10 years, Jen? <Laugh>

Jennifer Roberts (00:35:02):

Well, actually, this year it rained a lot. It rained a lot in San Diego. Which is actually very high-interest for them. ‘Cause they wanna know, is it gonna be raining at lunchtime?

Eric Cross (00:35:12):

Jen, you said something … you have your students writing about data?

Jennifer Roberts (00:35:16):

Oh yeah.

Eric Cross (00:35:17):

Can you tell me more about that?

Jennifer Roberts (00:35:19):

So, this is something we’ve done with the ninth grade team for a long time now, is writing about their own data. So it started with a unit about stereotypes and stereotype threat. And they would collect data individually and then they would enter that data into a Google form and then we would give them the spreadsheet of the aggregate data from the whole ninth grade. And then we morphed that unit into one about academic honesty, and they filled out a survey at the beginning of the unit about their feelings about academic honesty and about experiences with academic honesty and cheating and homework and things like that. And then we would do the unit. We’d do all the readings in the unit. And they’d have these “aha” moments about things that were happening at other schools. And then at the end of the unit, we would give them back their own aggregate data and ask them to write about whether or not academic honesty was an issue at our school. And then to support that answer with evidence from their own dataset. So they had that spreadsheet to comb through and figure out, you know, where am I gonna stand on this? We give them the multiple-choice questions we gave them as the graphs, in Google Slides, so that they could write about them and talk about them, too. So yeah, getting kids to write about data. And the the sentence frames we gave them were sentence frames out of, They Say, I Say, from the chapter on writing about science. And <laugh> as they write this stuff, they’re like, “I feel so smart writing this way.” And I’m like, “I know, ’cause you’re writing about big important topics!” Right? And writing about their own data come to think of it is another great way to make an assignment both very personal to them, but also make it ChatGPT-proof, you know, if you’re looking for something that kids can’t just hand to the robot, the robot doesn’t have that data set.

Eric Cross (00:37:08):

Absolutely. And Donnie, at the elementary level, do you, do you make connections between science and literacy? In your class? You talked about with math, definitely with the solar system, but now, I’m curious, what are your newer projects? What have you been working on lately?

Jennifer Roberts (00:37:23):

What’s up now, Donnie?

Eric Cross (00:37:24):

Yeah, what are you doing?

Donnie Piercey (00:37:25):

Oh, man. Well, let me think. I’m just trying to think of some fun projects that we’ve done this year. Science that we can tie in Literacy and also some student creation. Just recently we had a … so I’ve wanted to expose my students to famous scientists that weren’t just white dudes from Europe. So for this year, what I did — and I actually used AI for this — I went into ChatGPT and I asked for 64 famous scientists and it listed them all off. And then I asked it, like, how many of these were white? And I think it said like 61 of them. You know, it had like Neil DeGrasse Tyson, and a couple of other … I didn’t know who they were. So I’m like, “All right, so we need to make this more diverse and make this more equitable.” ‘Cause you know, with the student population in my classroom, try to find equal representation to make sure they can see themselves in some of these scientists. So, eventually got it narrowed down to where I had about 64 scientists. Half are women, half are men from all continents except Antarctica. I assigned these scientists to my students. Some got two; some got three. And their assignment was to go and one, do some individual research on this person, find out what they were famous for, what they were most well-known for, turn it actually into a persuasive piece, where I said, “Hey, you’re gonna have one slide.” And I’ll tell you why I gave him one slide in a minute. On that one slide, you’ve gotta convince the person who sees it that this scientist is the most important scientist since the dawn of creation. I said, “You could use images, text — I don’t care if they were famous for something that you didn’t even understand what it was. It’s a persuasive piece. You’re 10. Go all out. Add gifs, do that whole thing.

Eric Cross (00:39:21):

This is awesome.

Jennifer Roberts (00:39:21):

I wanna do this project.

Donnie Piercey (00:39:23):

And if you picked up on the number 64, and I did this in March, so what we did was throughout the weeks of March Madness of the women’s and men’s NCAA tournament, whenever a game was going on, we had another round of voting. I just paired ’em up. I was gonna like seed them, like 1 to 64 — that’s just way too much work for me <laugh>. So I just kind of did random kind of thing. But all the students had to do — they just saw the slides side-by-side, and the only question they had was, “Based on what you see here, who is the most important scientist? This person or this person?” And it eventually came down to Carl Sagan going up against Marie Curie.

Eric Cross (00:40:04):

OK, that’s a good matchup.

Donnie Piercey (00:40:06):

Yeah, well, the Marie Curie slide, they just liked the radium piece. So they added like some green glowing gifs. And I said, “Guys, it doesn’t always grow glow green.” But whatever. Anyway, eventually Carl Sagan, in case you wanted to know, according to the 10-year-olds in my classroom, is the most important scientist in the history of the world. So I don’t know if I agree with that per se — I think maybe Newton or somebody else might have had something else to say about it — but fun assignment. It was a unique way to expose my students to a bunch of ideas. I remember the student that I assigned Newton, the only thing that that she knew about Isaac Newton was “Didn’t he get hit in the head with an apple?” And I said, “Well, not exactly, I think you might have read or maybe seen too many like old-school cartoons or whatever.” But she ended up doing some research. She’s like, “Oh, I’ve heard of that before! That equal and opposite reaction thing.” Didn’t know what it meant. I had another student that just got really … you know, if you’ve ever been on one of those YouTube kicks where it’s just, you go like nine levels deep onto like, “What does this theorem mean?” Student sits in back of my classroom, I walked by one day and he’s just watching something on like the fifth dimension and what it might be. And I said, “Oh, your scientist got you started on that.” So definitely was a lot of fun. Unique way to combine reading, writing, but also expose my students to some ideas. And we’re definitely gonna do it again. I’ve actually done this assignment before. I picked 64 random elements on the periodic table. But their only slide that they have to make is “What’s your element? What is it used for? And then, why is this the most important element since the dawn of creation?” <Laugh> And, you know, there’s always that student that gets hydrogen. They’re just like “Sweet!” Right? They get excited about that one. <laugh>

Eric Cross (00:41:59):

Explosions.

Donnie Piercey (00:42:00):

Yeah. But then, for that kid who likes a challenge, or that student with the “gifted” label, you give them, like, einsteinium or palladium. Some of the more challenging ones. And they go all out with this. I didn’t use AI for that one, but it was kind of fun, and I figured it’d be neat to share an idea that another teacher could try.

Eric Cross (00:42:20):

Well you probably have at least two teachers right now that are gonna go and try that. And we’re both looking at you. So.

Donnie Piercey (00:42:24):

Go for it.

Eric Cross (00:42:25):

Thanks for that idea. I’m imagining my students coming in with jerseys with “neon.”

Donnie Piercey (00:42:29):

Oh yeah. <laugh>

Eric Cross (00:42:30):

“Neon” on it. Just all ’80s out.

Donnie Piercey (00:42:33):

The game behind it, too, is you tell kids — again, this is just so the 10-year-olds in my class don’t get their feelings hurt — but I say, “Hey, and if your element gets knocked out, you just have to start cheering for whoever beats you in the tournament.” So by the end, you kind of got half the class cheering for one and half the class cheering for whatever.

Jennifer Roberts (00:42:53):

So the only thing I got outta that whole story that I’ve got for you is, as a child I met Carl Sagan. That’s all I got.

Donnie Piercey (00:43:02):

For real?

Jennifer Roberts (00:43:02):

For real.

Donnie Piercey (00:43:03):

So did he talk with that cadence and tone?

Jennifer Roberts (00:43:06):

Yes.

Donnie Piercey (00:43:06):

Like in real life? Wow.

Jennifer Roberts (00:43:07):

Yes. My father was one of the cinematographers on the original Cosmos. And I got to go to the set a few times.

Donnie Piercey (00:43:14):

That’s incredible!

Jennifer Roberts (00:43:15):

I did not appreciate what I was seeing as a child. But as an adult, I’m like, “That was cool. I was there.”

Donnie Piercey (00:43:20):

“You can see my shadow off in the distance.”

Jennifer Roberts (00:43:23):

I mean, maybe that’s part of why I’ve always had an interest in science. I’ve always had fantastic science teachers. Every science teacher I ever had was amazing.

Donnie Piercey (00:43:31):

I credit mine to Mr. Wizard. I don’t know if you ever watched Mr. Wizard and Beakman’s World?

Eric Cross (00:43:35):

I remember Mr. Wizard. Yep. Yep. I definitely remember Mr. Wizard, Beakman’s World, all those. That was on Nickelodeon back in the day. I had to get up early to watch that one. But there’s a YouTube video—

Donnie Piercey (00:43:44):

Six am!

Eric Cross (00:43:44):

<laugh> It was! It was super-early! But there was one, Don, I don’t know if you’ve seen this on YouTube, but it said “Mr. Wizard Is Mean,” and it’s just clips of when he’s—

Donnie Piercey (00:43:56):

Yelling at kids!

Eric Cross (00:43:56):

Chastising. Or being really direct. It’s just one after another.

Donnie Piercey (00:44:02):

He always asked ’em a question and if the kid, you know, didn’t answer it right, he’d be like, “Well, you’re not right, but you’re wrong.” You know, whatever. <Laugh>

Eric Cross (00:44:14):

I have to make sure I’m not subconsciously saying Mr. Wizard quotes when I’m talking in the classroom, when things are happening. But yeah, that video’s hilarious. So I just want to bring us back to AI, and ask this question: Do you think science has a special role to play when it comes to teaching kids about AI responsibly? Does science have a special role in that?

Jennifer Roberts (00:44:36):

I think the responsible piece of AI I wanna teach my students about is the part about the bias in the algorithms and the bias in the training. And I want them to understand how it works, well enough to make informed decisions about how it impacts their lives.

Donnie Piercey (00:44:56):

Hmm.

Jennifer Roberts (00:44:57):

Because I do have concerns about a tool that was trained on the internet. And the answers it gives you is the average of the internet. And do we trust the internet? And the answer from kids is always, “Well sorta, no.” <Laugh> So I want them to understand the social science behind that.

Donnie Piercey (00:45:18):

Yeah. And just along that same point, having the students recognize that just because, you know, you copy-and-paste a question in, the answer it spits out might not always be correct. So, teaching them that just like you would with a source that you find about a topic that you’re researching, you’ve gotta fact-check.

Jennifer Roberts (00:45:44):

It’s just like being a good scientist. A good scientist wouldn’t always accept a single result or the first result. You know, you would look at multiple angles. You would try things different ways. Last week I took the article my seniors were reading about victim compensation after 9-11, and in front of them, I gave ChatGPT, I said, “Are you familiar with this article by Amanda Ripley? And ChatGPT came back and said, “Oh yes, this was written in the Atlantic in 2020 and it’s about these things, blah, blah blah.” And my students looked at that and went, “That’s not the article we read.” And I said, “I know. It got it wrong. That’s amazing!” Yeah. And I was so happy that it got it wrong! ‘Cause I wanted them to see that happen.

Donnie Piercey (00:46:21):

And I guess one of the big science questions there, or one of the big science components there, is that idea of inquiry. Right? It’s almost like you have to teach students how to ask those deep questions about what AI spits out.

Eric Cross (00:46:35):

All of those tips are great. And it leads me to this last question I want to ask. New teachers that are out there — it actually doesn’t even matter; new teachers, experienced teachers, all of us are kind of new at different levels of this race. We’re all kind of starting it together. I mean, it hit mainstream. We’re all getting exposed to it. You all really dive into it. When tech comes out, I know you two really like, “OK, how can we use this to transform education and do awesome things for kids?”

Donnie Piercey (00:47:04):

Usually, when new tech comes out, “How can this make my life easier?” is usually the question. Yeah.

Jennifer Roberts (00:47:09):

“How can I save myself time with this?” Yes.

Donnie Piercey (00:47:11):

“How can this result in me watching more TV and you know, less grading,” sometimes.

Eric Cross (00:47:16):

And I start there like you, but then I end up more time that I fill with another project. And I need to learn how to stop doing that. I’m like, “Oh! I got more free time! … to go take on this other task.”

Jennifer Roberts (00:47:28):

Oh, all of my tech adoption is driven by “how can I work less?”

Eric Cross (00:47:32):

So you’re you’re talking to a new teacher, teacher’s getting exposed to this, they’re starting the school year or they’re just getting their feet wet with it. What advice would you give them about AI, incorporated into content or even just best practices? Where you’re at right now in your own journey, and someone’s asking you about it —what would you share with ’em? And Jen, I want to start with you.

Jennifer Roberts (00:47:53):

So, the first thing I did is I was in the middle of grading, you know, 62 essays from my seniors about Into the Wild, when ChatGPT became a thing last November. And I wanted to see what would happen. So the first thing I did was take the prompt that I had given my students and gave it to ChatGPT, ’cause I had just graded a whole bunch of those essays and my brain was very attuned to what my rubric was doing and what I was expecting as the outcome. So I could take what ChatGPT gave me as that quote unquote “essay” and evaluate it critically. And I was ready to do that. So my first advice is take something you’re already asking students to do and ask ChatGPT to do the same thing. So that as you look at the student results, you can compare that to what ChatGPTgives you. If what you’re finding is that ChatGPT can generate something that would earn a decent grade from you, you might need to change that assignment. And it doesn’t need to be a big change, but it might need a tweak or something, so that it, it does rely on the student voice, the students to do something more personal. I’m finding very helpful in my classroom is having my kids do projects where they are recording themselves on — I like Flip. So they’re writing a scene together and they’re having to record the scene together. And I’m emphasizing more of the speaking roles than the writing roles necessarily. So yes, first, take something you’re already doing, paste in to ChatGPT, see what the results are, see how that fits with what your students are doing, and then do that for every assignment you give and just sort of see what comes out of that, and see which assignments are failing and which assignments are working. ‘Cause that’s gonna give you a sense, when you do see one of those results from your students, you’ll be able to recognize it. But it’ll also help you tweak your assignments and decide, “How can I make this a little more original or a little bit more authentic for my students?” And if the robot, if the AI, can’t generate a response, what could the AI do that would be helpful to your students? Would be my next question. So can you use the AI to help them generate an outline? Can you use the AI to help them generate a list of steps to help them get started? And when you’re comfortable enough doing that by yourself, then don’t be afraid to open it in front of your class. If it’s not blocked at your school site, which I hope it’s not. Because I think the advantage goes to kids who have access to this in the long run, or at least see what it is and know what it is. Right? Because if a kid graduates from school without knowing that AI exists, they’re not gonna be prepared for what they face out in the world. So give them a chance to see you using it. Model effectively using it. I have a blog post about that. I just wrote it. LitAndTech.com. You can check that out. “Introducing 9th graders to ChatGPT.” How it went, right? There’s a chart there you can have. It’s my very first draft of this, but it seems to be very popular. So, you know, show students how it can be used as their mentor. If I can’t come read your paragraph because I have 36 kids in my classroom and I cannot stop and read everybody’s first paragraph, can you, if you want to, give your first paragraph to ChatGPT and ask for advice? And will that advice be helpful to you? So showing students how it can be used responsibly is, I think, something every teacher should be doing right now. And don’t hold back just because you’re afraid you’re gonna be teaching them what this is. They know what this is. Right?

Donnie Piercey (00:51:13):

They know what it is.

Jennifer Roberts (00:51:13):

Especially if you teach high school. They know what it is. I’ve had parents thank me for showing them how to use it responsibly. You know, this can actually be a really useful tool, but if you’re trying to make it do your work for you, it will probably fail you. If you’re trying to use it to help you do your work, it will probably be helpful. Sort of the way I’m breaking it down for them at this point. You want the great metaphor? The great metaphor is if you build a robot and send it to the top of a mountain, did you climb that mountain? No. If you build a robot and ask it to help you get to the top of the mountain, and you and the robot go together, did you climb that mountain? Yes.

Eric Cross (00:51:53):

I like that. I’m thinking through this. I’m processing that now.

Donnie Piercey (00:51:57):

Me too.

Eric Cross (00:51:59):

Yeah. I just imagine a robot holding my hand climbing Mount Everest and I’m like, “Yeah, I did it.”

Donnie Piercey (00:52:04):

If I got a robot though, like I would have to dress it like Arnold Schwarzenegger in Terminator 2. Like I would just have to.

Eric Cross (00:52:10):

Of course.

Donnie Piercey (00:52:10):

Of course.

Eric Cross (00:52:13):

Donnie, same question. Advice. Teachers getting immersed into it. Tips. What would you say?

Donnie Piercey (00:52:20):

So, I would definitely agree with everything that Jen said. Just, if anything else, to familiarize yourself with it. Almost like pretend like it’s a student in your classroom and it’s answering questions, just so that way you can see what it can do. And you’re kind of training yourself, like, “Oh, well, if I ever need examples, exemplars.” If you’re in a writing piece and you don’t wanna sit there and write out four different types of student responses — you know, advanced writer, beginning writer, whatever — great way to to do that is you just—

Jennifer Roberts (00:52:48):

Oh yeah. We did that.

Donnie Piercey (00:52:48):

—copy the prompt in and give a beautifully written piece that a fifth grader would be impressed with. Boom. It’ll do it for you. In my classroom, the way that I approach it is I kinda look at AI as almost like this butler that I don’t have to pay. That if I need it to do something for me, it’s just bookmarked. I can click it. And I mean, sometimes I just talk to it like it’s a person. And it’s almost like, in the chat window, I’m just rambling at it, what I’m trying to do. And it’s almost like I’m talking to a coworker, and I’m trying to hedge out some ideas for a lesson. Simple example: For a science lesson, if you’re trying to come up with … let’s say you’re a fifth-grade — or, sorry, I teach fifth grade. Say you’re a seventh-grade science teacher. And you’re trying to teach the students in your class about Newton’s third law of motion. You know, every action [has an ] equal and opposite reaction. Look around your room. See what you have. Maybe look around and you’re like, “All right, I got a whiteboard, microscope, I’ve got magnets, a cylinder. …” And you just copy all this stuff into ChatGPT. Say, like, “Hey, I have all of these items. Cotton balls, peanut butter, whatever.” And say, “I’m trying to teach students Newton’s third law of motion. Give me some ideas of some ways I could teach it using some of these materials.” And it’ll do it! It’ll give you like five to 10 ideas!

Jennifer Roberts (00:54:15):

And then tell it what your students are into. Like, my students are really into basketball. Can you work that into this lesson?

Donnie Piercey (00:54:21):

Yeah! They’re into the Avengers! Hey, find some way to tie Spider-Man into this. You know, that was a pun that didn’t go so well. But, you know <laugh> figure out some way that you could incorporate this and it’ll do it. And Eric, like you said, it won’t be perfect. Right? But if anything else, if you’re a starting teacher and you’re trying to brainstorm ideas — try it.

Eric Cross (00:54:44):

And Donnie, as you were saying that, I was thinking — first, I imagined Spider-Man shooting cotton balls with peanut butter all over them — and then my mind went to having students have these items, like you were saying. And then they create labs, working alongside AI. To do inquiry. To create a lab about something, and then going and performing and collecting data. OK, that’s — now I wanna go do that tomorrow!

Donnie Piercey (00:55:10):

Listen, it is so easy to do. If you have an extra computer in your classroom. … We were talking about Jarvis and Iron Man and Tony Stark earlier. Make a new chat in ChatGPT. Tell it, “I want you to pretend that you are Tony Stark. Only answer questions as if you are Tony Stark.” Or “Pretend you’re Jarvis.” Whatever. “Stay in character the whole time. I’m going to have sixth grade students come up to you and ask you questions about science or forces of nature, and only answer questions like you’re Iron Man.” And guess what? You keep that station in your classroom. Students are working on a project — you know, in elementary school, a lot of times we’ll have that, “ask three before me” — you’re supposed to ask three friends before you go and bug the teacher. Well, maybe one of those “three before me” can be that little computer station, where they go up and ask Tony Stark a question, and then it answers them as Jarvis or Iron Man. I mean, we’re really just scratching the surface with all this AI stuff. And as more and more companies and more and more creatives are gonna start to realize everything that it can do, we’re gonna start to see it more and more. And hopefully we as teachers can really figure out how to use this tool to, of course, help students, but also help them be creative and explore and learn on their own.

Eric Cross (00:56:35):

That’s amazing. And just both of you are just dropping gems right now. And I wanna wrap up by saying — and I’ve said this before on earlier podcasts I’ve done — but at this phase in my life, the people that I’m the biggest fans of are teachers. And it’s true. I don’t mean that in a cliche way. When I watch celebrities and things like that, when I watch professional sports, that doesn’t fill me the way it used to when I was a kid. At this point, as a professional, I get inspired by other educators who are just doing awesome things. And when I think about educators who are doing that, you two are on that list of people that make me better. And when I get better, I can do better things for my kids. And so, one, I want to thank you for staying in the classroom and continue to support students. They’re so lucky to have you both. The second thing I wanted to say is, Jen, I wanna start with you. Where can people — and I know we said at the beginning — but where can people find the stuff that you put out? You got blogs, your social, your book.

Jennifer Roberts (00:57:28):

I got lots of social. Twitter, I’m JenRoberts1 on Twitter. And then my blog is LitAndTech.com. And then I’m on lots of the new social too, the Mastodons, the Spoutables, the Posts — those kinds of things — as just Jen Roberts, because I got in early and I got my real name without a 1. And there was some other one I’m on recently that I’ve forgotten about. But there’s lots of ’em. They’re fun. And I’m Jen Roberts. You can find me there.

Donnie Piercey (00:57:56):

And I’m SergeantPepperD on AOL, if anyone’s interested.

Eric Cross (00:58:00):

If you wanna hit Donnie up on AIM. <Laugh>

Donnie Piercey (00:58:03):

SergeantPepperD.

Jennifer Roberts (00:58:04):

You know, speaking of rock stars and people who do amazing things, I did write a blog post about using ChatGPT in the classroom, but I hear Donnie wrote a whole book.

Eric Cross (00:58:13):

Oh yeah. So, Donnie! Donnie, that’s a great segue. Thanks Jen. Donnie, how do people find out more? And can you tell us about this book you wrote, that’s coming out in the summer?

Donnie Piercey (00:58:22):

Yeah, so the book I wrote is called 50 Strategies for Integrating AI Into the Classroom. It’s published by Teacher Created Materials. They reached out to me. They had seen some of the stuff that I was doing, not just with ChatGPT, but also some image-generating AI stuff. You know, I got featured on Good Morning America, which was kind of cool. And they saw that and they said, ‘Hey, that looks really neat.” Reached out to me and asked me to write a book. And the idea behind the book, that launches this summer, it’s just 50 ideas, 50 prompts, different things that, as a classroom teacher, that you can do. So, you know, I think there’s so many AI books that are out there now. A lot of them are big ideas, which I think are important. Definitely important discussions that need to be, have around, the ethics of AI. What’s the role that AI should play in the classroom. But I just wanted to write a book, kind of like the discussion that, that Jen and I were just having, which is like, “Can we just share a whole bunch of ideas, different things that we could try with our students?” So definitely check it out. And I appreciate you giving me a shout-out too. That was cool, Eric. Thank you.

Eric Cross (00:59:35):

Of course. Definitely. And Donnie, your Twitter is again. …

Donnie Piercey (00:59:39):

Oh, @MrPiercey, M R P I E R C E Y.

Eric Cross (00:59:44):

Follow Donnie. Follow Jen. Tons of stuff on there. Both of you, thank you so much. For your time, for talking about students and how we can take care of them, science, literacy, AI. I hope we can talk about this again. I feel like even if in just six months, we might be saying different things. In a year, the landscape might completely change. And that makes it really fun. But thank you both for being on the show.

Jennifer Roberts (01:00:04):

Thank you for having us, Eric.

Donnie Piercey (01:00:05):

Thank you so much, Eric. We appreciate it, bud.

Eric Cross (01:00:10):

Thanks so much for listening to my conversation with Jen Roberts and Donnie Piercey. Jen Roberts is a veteran English teacher at San Diego’s Point Loma High School and author of the book Power Up: Making the Shift to 1:1 Teaching and Learning. You can keep up with her at LitAndTech.com. And Donnie Piercey is a fifth-grade teacher from Lexington, Kentucky. He hosts the podcast Teachers Passing Notes. Stay up-to-date with him at Resources.MrPiercey.com. And let us know what you think of this episode in our Facebook discussion group, Science Connections: The Community. Make sure you don’t miss any new episodes of Science Connections by subscribing to the show, wherever you get podcasts. And as always, we’d really appreciate it if you can leave us a review. It’ll help more people and AI robots find the show. You can find more information on all of Amplify’s shows on our podcast hub, Amplify.com/hub. Thanks again for listening.

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What Jennifer Roberts says about science

“If I’m not teaching my students how to use this, then they’re not going to turn into the adults we need them to be… If we’re not at least trying to think about what our future world is going to look like, then we’re not serving our students well.”

– Jennifer Roberts

High School English Teacher

Meet the guests

Jen Roberts is a Nationally Board Certified high school English teacher with 25+ years of experience teaching Social Science and English Language Arts in grades 7-12. She has had 1:1 laptops for her students since 2008 and is the co-author of Power Up: Making the Shift to 1:1 Teaching and Learning. A Google for Education Certified Innovator since 2011, Jen was named the CUE Outstanding Educator in 2022. Her interests include literacy instruction, standards based grading, and leveraging Google tools to make her teaching more efficient and effective.

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Donnie Piercey, the 2021 Kentucky Teacher of the Year, is a fifth-grade teacher in Lexington, Kentucky.  With a passion for utilizing technology to promote student inquiry, learning, and engagement, he has been teaching since 2007. In addition to being in the classroom, he runs a podcast, Teachers Passing Notes that is produced by the Peabody Award winning GZMShows, and holds several recognitions, including a National Geographic Fellowship to Antarctica in 2018. His most recent work in Artificial Intelligence has not gone unnoticed, earning him multiple appearances on Good Morning America, the Associated Press, and PBS. His upcoming book, “50 Strategies for Integrating AI in the Classroom” published by Teacher Created Materials, is written for educators looking for practical classroom approaches to using AI. All told, Donnie has been invited to keynote and present at schools in thirty-three states and on five continents.

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A laptop screen displays the “Science Connections: The Community” private group page, with science-themed icons decorating the background and edges.

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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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.

Download Transcript

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.

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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. Listen here!

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With Amplify Science, students don’t just passively learn about science concepts.

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Listen to these educators share how the program empowers students to think, read, write, and argue like real scientists and engineers every day.

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Abstract art with vibrant colors featuring a yellow silhouette of a person holding a book against a background of geometric shapes, swirling patterns, and bold textures.

Unit 1

Microbiome

Domain: Life Science

Unit type: Launch

Student role: Microbiological researchers

Phenomenon: The presence of 100 trillion microorganisms living on and in the human body may keep the body healthy.  

Abstract artwork of a person's side profile with geometric shapes and colorful patterns flowing from the head, holding a small sledgehammer. A vision chart is visible in the corner.

Unit 2

Metabolism

Domain: Life Science

Unit type: Core

Student role: Medical researchers

Phenomenon: Elisa, a young patient, feels tired all the time.  

Orange abstract background with hexagonal shapes featuring icons of a bar chart, plant, safety vest, test tube, peach, and stethoscope.

Unit 3

Metabolism Engineering Internship

Domains: Life Science, Engineering Design

Unit type: Engineering internship

Student role: Food engineers

Phenomenon: Designing health bars with different molecular compositions can effectively meet the metabolic needs of patients or rescue workers.  

An image showing a graphic of spiders of different colors with distinct leg and body patterns, including brown, yellow, and blue variations. The background is a dark, textured surface.

Unit 4

Traits and Reproduction

Domain: Life Science

Unit type: Core

Student role: Biomedical students

Phenomenon: Darwin’s bark spider offspring have different silk flexibility traits, even though they have the same parents.  

Illustration of a person in a red hat and fur-lined coat with eyes closed, surrounded by large orange circles on a dark background.

Unit 5

Thermal Energy

Domain: Physical Science

Unit type: Core

Student role: Thermal scientists

Phenomenon: One of two proposed heating systems for Riverdale School will best heat the school. 

Abstract artwork depicting a bright sun with blue and orange swirling patterns next to green hills under a sky with shades of blue, orange, and red.

Unit 6

Ocean, Atmosphere, and Climate

Domains: Earth and Space Science, Physical Science

Unit type: Core

Student role: Climatologists

Phenomenon: During El Niño years, the air temperature in Christchurch, New Zealand is cooler than usual.  

Illustration of a village with houses, fields and mountains under a cloudy sky with waves of wind or rain.

Unit 7

Weather Patterns

Domains: Earth and Space Science, Physical Science

Unit type: Core

Student role: Forensic meteorologists

Phenomenon: In recent years, rainstorms in Galetown have been unusually severe.  

A polar bear stands on a small ice floe in the ocean with an orange sun in the sky and distant icy mountains in the background.

Unit 8

Earth’s Changing Climate

Domains: Earth and Space Science, Life Science

Unit type: Core

Student role: Climatologists

Phenomenon: The ice on Earth’s surface is melting.  

Abstract geometric design in shades of blue and purple featuring a hexagon with icons of a building, wrench, molecules, sun, paint can, and screwdriver.

Unit 9

Earth’s Changing Climate Engineering Internship

Domains: Earth and Space Science, Engineering Design

Unit type: Engineering internship

Student role: Civil engineers

Phenomenon: Designing rooftops with different modifications can reduce a city’s impact on climate change.  

A barren, rocky desert landscape with rover tracks leading to a distant vehicle on a hill under a hazy sky.

Unit 1

Geology on Mars

Domain: Earth and Space Science

Unit type: Launch

Student role: Planetary geologists

Phenomenon: Analyzing data about landforms on Mars can provide evidence that Mars may have once been habitable. 

Two prehistoric reptiles with long snouts and tails are near the shore, one on land and one in water, with plants, rocks, and an island in the background.

Unit 2

Plate Motion

Domain: Earth and Space Science

Unit type: Core

Student role: Geologists

Phenomenon: Mesosaurus fossils have been found on continents separated by thousands of kilometers of ocean, even though the Mesosaurus species once lived all together.  

Geometric design featuring a telescope, mountain, sound waves, and cosmic elements on a purple hexagonal background.

Unit 3

Plate Motion Engineering Internship

Domains: Earth and Space Science, Engineering Design

Unit type: Engineering internship

Student role: Mechanical engineering interns

Phenomenon: Patterns in earthquake data can be used to design an effective tsunami warning system.  

Illustration of a cross-section of Earth showing a volcano near the ocean. Trees, mountains, and clouds are visible above, with subterranean layers below.

Unit 4

Rock Transformations

Domain: Earth and Space Science

Unit type: Core

Student role: Geologists

Phenomenon: Rock samples from the Great Plains and from the Rocky Mountains — regions hundreds of miles apart — look very different, but have surprisingly similar mineral compositions.  

Illustration showing the stages of melting an orange popsicle: whole, partially melted, more melted, and almost completely melted, with wooden sticks, on a purple background.

Unit 5

Phase Change

Domains: Physical Science, Earth and Space Science

Unit type: Core

Student role: Chemists

Phenomenon: A methane lake on Titan no longer appears in images taken by a space probe two years apart

Green geometric background with a hexagonal emblem containing a parachute icon, ruler, bandage, and stacked layers on a gradient pattern.

Unit 6

Force and Motion Engineering Internship

Domains: Engineering Design, Physical Science

Unit type: Engineering internship

Student role: Mechanical engineering interns

Phenomenon: Designing emergency supply delivery pods with different structures can maintain the integrity of the supply pods and their contents.  

Abstract digital artwork featuring numerous red and gray circles overlapping a split background of blue and light purple, creating a dynamic and energetic composition.

Unit 7

Chemical Reactions

Domains: Physical Science, Life Science, Earth and Space Science

Unit type: Core

Student role: Forensic chemists

Phenomenon: A mysterious brown substance has been detected in the tap water of Westfield.  

An illustration of a whale with jellyfish and turtles from Amplify Science

Unit 8

Populations and Resources

Domains: Life Science, Earth and Space Science

Unit type: Core

Student role: Biologists

Phenomenon: The size of the moon jelly population in Glacier Sea has increased. 

Low-poly landscape with trees and mushrooms. A fox sniffs the ground, a rabbit sits nearby, and mountains and sun are in the background.

Unit 9

Matter and Energy in Ecosystems

Domains: Life Science, Earth and Space Science, Physical Science

Unit type: Core

Student role: Ecologists

Phenomenon: The biodome ecosystem has collapsed.  

Two people climbing rocky terrain; illustrations show a hiking boot and a belt with gear.

Unit 1

Harnessing Human Energy

Domains: Physical Science, Earth and Space Science, Engineering Design

Unit type: Launch

Student role: Energy scientists

Phenomenon: Rescue workers can use their own human kinetic energy to power the electrical devices they use during rescue missions.  

A spacecraft approaches and docks with a space station featuring large blue solar panels, set against a backdrop of outer space.

Unit 2

Force and Motion

Domain: Physical Science

Unit type: Core

Student role: Physicists

Phenomenon: The asteroid sample-collecting pod failed to dock at the space station as planned.

Green geometric graphic featuring icons: a baby, thermometer, layers, medical alert, and a flame.

Unit 3

Phase Change Engineering Internship

Domains: Engineering Design, Physical Science

Unit type: Engineering internship

Student role: Chemical engineering interns

Phenomenon: Designing portable baby incubators with different combinations of phase change materials can keep babies at a healthy temperature.  

Illustration of a roller coaster filled with people, hands raised, going down a steep track against a bright blue sky with clouds.

Unit 4

Magnetic Fields

Domain: Physical Science

Unit type: Core

Student role: Physicists

Phenomenon: During a test launch, a spacecraft traveled much faster than expected.  

Illustration of Earth with arrows and wavy lines representing solar radiation entering the atmosphere, showing a focus on the Asia-Pacific region.

Unit 5

Light Waves

Domains: Physical Science, Life Science, Earth and Space Science

Unit type: Core

Student role: Spectroscopists

Phenomenon: The rate of skin cancer is higher in Australia than in other parts of the world.

A city skyline at night with a prominent full moon, stars in the sky, and a bridge silhouette on the left.

Unit 6

Earth, Moon, and Sun

Domains: Earth and Space Science, Physical Science

Unit type: Core

Student role: Astronomers

Phenomenon: An astrophotographer can only take pictures of specific features on the Moon at certain times.  

Four low-poly dinosaurs with missing body sections are standing in a row; one is yellow, and the others are green. They have purple spikes and red patches on their bodies.

Unit 7

Natural Selection

Domains: Life Science, Earth and Space Science

Unit type: Core

Student role: Biologists

Phenomenon: The newt population in Oregon State Park has become more poisonous over time.  

Red geometric background with icons including a mosquito, DNA strand, bar chart, and world map inside a hexagon.

Unit 8

Natural Selection Engineering Internship

Domains: Engineering Design, Life Science

Unit type: Engineering internship

Student role: Clinical engineers

Phenomenon: Designing malaria treatment plans that use different combinations of drugs can reduce drug resistance development while helping malaria patients.  

Two giant tortoises with long necks stand near water; one tortoise feeds on leaves from a tree while the other is near dense vegetation.

Unit 9

Evolutionary History

Domains: Life Science, Earth and Space Science

Unit type: Core

Student role: Paleontologists

Phenomenon: A mystery fossil at the Natural History Museum has similarities with both wolves and whales.    

Access program

Watch the video to the right plus the ones below showing you how to navigate our digital platform. When you’re ready, follow the instructions below to log into our live demo account.

  • 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

Navigating an Engineering Internship (Part 1)

This Part 1 video demonstrates how Engineering Internship units invite students to design solutions for real-world problems as interns for a fictional company called Futura. In the process, they apply and deepen their learning from Core units.

Navigating an Engineering Internship (Part 2)

This Part 2 video demonstrates how to use the Futura Workspace to manage the immersive experience of the Engineering Internship units. This includes guidance on how to create student groups, how to review student work, and how to send students targeted feedback on their designs.

Navigating our reporting tools

Teachers of Amplify Science grades 6–8 have access to a feature called Reporting. When unit assessments are administered digitally, the Reporting tool enables teachers to analyze student performance on the unit assessments.

Differentiation post-assessment

Every core unit of Amplify Science 6–8 features a formal formative assessment opportunity at the mid-way point, or “Critical Juncture,” of the unit, which provides an important opportunity for differentiation.

Resources

An adult sits on a couch using a laptop while a child next to them does homework in a notebook.

Remote and Hybrid Learning Guide

Learn more about new product enhancements and resources to help you and your sta…

Two students collaborate at a desk, discussing a science workbook. Other students are visible in the background, engaged in the vibrant atmosphere of the classroom.

Course structure for 6–8

Take a closer look at how the program is organized.

Illustration of a roller coaster filled with people, hands raised, going down a steep track against a bright blue sky with clouds.

Unit phenomena for 6–8

Take a closer look at the middle school unit phenomena featured in each grade le…

A laptop screen displays a simulation about Earth's energy system, with surrounding images showing diagrams and energy flow models.

Classroom Slides for 6–8

Classrooms Slides for middle school are coming soon! These customizable PowerPoi…

A laptop screen displaying a map with three ecosystem options, each illustrated by different animal icons and accompanied by relevant data lists.

Sims for 4–8

Take a closer look at the digital Simulations included at each grade level.

A student reviews a science textbook and looks at a laptop in a classroom, while other students work together on their science projects in the background.

Active reading in 6–8

Learn how we support students in learning how to interact with scientific texts….

A young person wearing gloves looks through a microscope at a table with laboratory supplies, including bottles, slides, and a tray, against a plain blue background.

Investigations for 6–8

Explore the types of investigations that take place in middle school classrooms….

A collection of assorted electronic components and supplies, including batteries, motors, wires, switches, rubber bands, small propellers, cups, solar panel, bulbs, and fasteners.

Materials Kits for 6–8

See what components come in our materials kits!

Two students sit at desks writing in notebooks and using laptops in a classroom setting.

Approaches to assessment in 6–8

Learn about our middle school embedded assessments.

Get in touch

Smiling man with short hair and a trimmed beard wearing a light blue collared shirt against a plain white background.

Have questions? Bob McCarty is standing by and ready to help.

Robert “Bob” McCarty
Senior Account Executive
(435) 655-1731
rmccarty@amplify.com

What’s included

Along with compelling print materials, powerful digital resources, and more hands-on materials than any other program, Amplify Science California also includes engaging and realistic experiences, access to diverse role models, countless a-ha moments, and the inspiration and confidence to consider a future as a scientist or engineer.

Choose level

K–56–8

Year at a glance

Amplify Science California is organized around units where students explore compelling phenomena and real-world problems, develop and strengthen claims by collecting evidence and testing assumptions, and apply their learning in new contexts.

Educational curriculum chart showcasing a progression of amplify science lessons from kindergarten to grade 5, categorized by grade and subject areas like plants, animals, weather, and energy.

Units at a glance

In each Amplify Science California unit, students are asked to inhabit the role of a scientist or engineer in order to investigate a real-world problem. These problems provide relevant, 21st-century contexts through which students investigate different scientific phenomena.

An illustration from Needs of Plants and Animals unit

1

Needs of Plants and Animals

Students take on the role of scientists in order to figure out why there have been no monarch caterpillars in the community garden since vegetables were planted. They investigate how plants and animals get what they need to live and grow, and make a new plan for the community garden that provides for the needs of the monarch caterpillars in addition to producing vegetables for humans.

An illustration from the Pushes and Pulls unit

2

Pushes and Pulls

Students take on the role of pinball machine engineers as they investigate the effects of forces on the motion of an object. They conduct tests in their own prototypes (models) of a pinball machine and use what they learn to contribute to the design of a class pinball machine. Over the course of the unit, students construct a foundational understanding of why things move in different ways.

Silueta de una estructura de parque infantil contra un cielo azul con nubes y tres soles amarillos.

3

Sunlight and Weather

The principals of Woodland Elementary and Carver Elementary need student weather scientists to help them explain why Woodland’s playground is warmer than Carver’s at recess. Students gather data from models of the sun and Earth’s surface and observe their own playgrounds to figure out how sunlight causes changes in the temperatures of different surfaces. Students then use models to figure out why Woodland’s playground sometimes floods.

Illustration of sea turtles swimming among seaweed in the ocean, with a large shark in the background.

1

Animal and Plant Defenses

Students play the role of marine scientists. In their role, students apply their understanding of plant and animal defense structures to explain to aquarium visitors how a sea turtle and her offspring can defend themselves from ocean predators when they are released into the wild.

Dos manos sosteniendo un papel con un dibujo de pirámide y árbol, iluminado por una linterna, proyectando otra sombra de la imagen en la pared.

2

Light and Sound

Students take on the role of light and sound engineers for a puppet show company as they investigate cause and effect relationships to learn about the nature of light and sound. They apply what they learn to design shadow scenery and sound effects for a puppet show.

An illustration from the Spinning Earth unit

3

Spinning Earth

As sky scientists, students explain why a boy living in a place near them sees different things in the sky than his grandma does when he talks to her on the phone. Students record, organize, and analyze observations of the sun and other sky objects as they look for patterns and make sense of the cycle of daytime and nighttime.

An elephant standing next to a tree uses its trunk to pick a fruit from a branch while more fruit hangs above.

1

Plant and Animal Relationships

In their role as plant scientists, students work to figure out why there are no new chalta trees growing in the Bengal Tiger Reserve, which is part of a broadleaf forest. Students investigate what the chalta tree needs to survive, then collect and analyze qualitative and quantitative data to solve the mystery.

A hand holds a red bean on a table, while a wooden stick spreads white glue and scattered beans. Also on the table are a white cup and a yellow pen.

2

Properties of Materials

As glue engineers, students are challenged to create a glue for use at their school that meets a set of design goals. Students present an evidence-based argument for why their glue mixture will be good for their school to use.

Ilustración de una costa con acantilados, un edificio de centro recreativo con un techo rojo y un letrero, árboles de hoja perenne, una bandera azul y una playa de arena debajo.

3

Changing Landforms

The director of the Oceanside Recreation Center gets a scare when a nearby cliff collapses overnight. Research reveals that the distance between the Recreation Center’s flagpole and the edge of the cliff have changed over time. Students play the role of geologists and work to figure out why the cliff has changed over time. Based on what they learn about erosion, they advise on whether it is safe to keep the center open even though the cliff is changing.

An illustration from the Balancing Forces unit

1

Balancing Forces

People in Faraday are excited to hear that a new train service will be built for their city, but concerned when they hear that it will be a floating train. Students are challenged to figure out how a floating train works in order to explain it to the citizens of Faraday. They develop models of how the train rises, floats, and then falls back to the track, and then write an explanation of how the train works.

An illustration from the Inheritance and Traits unit

2

Inheritance and Traits

Students play the role of wildlife biologists working in Greystone National Park. They study two wolf packs and are challenged to figure out why an adopted wolf (“Wolf 44”) in one of the packs has certain traits. Students observe variation between and within different species, investigate inherited traits and those that result from the environment, and explain the origin of several of the adopted wolf’s traits.

An illustration from the Environments and Survival unit

3

Environments and Survival

In their role as biomimicry engineers, students work to figure out how the traits of grove snails affect their survival in different environments. They then explore how the traits of different organisms make them more likely or less likely to survive, collecting and interpreting data to understand how organisms’ traits affect their survival in different environments. Students then apply their understanding to a new challenge: designing effective solutions for the removal of invasive plants.

An illustration from the Weather and Climate unit

4

Weather and Climate

In their role as meteorologists, students gather evidence to decide where to build an orangutan reserve by analyzing patterns in weather data. After choosing the strongest evidence, students use data to make arguments about which of three fictional islands has weather most like that of orangutans’ existing habitats, Borneo and Sumatra. They then discern patterns in the locations of natural hazards in order to figure out which ones the Wildlife Protection Organization must prepare for.

An illustration from the Energy Conversions unit

1

Energy Conversions

Students take on the role of systems engineers for Ergstown, a fictional town that experiences frequent blackouts, and explore reasons why an electrical system can fail. Students apply what they learned as they choose new energy sources and energy converters for the town, then write arguments for why their design choices will make the town’s electrical system more reliable.

An illustration from the Vision and Light unit

2

Inheritance and Traits

As conservation biologists, students work to figure out why a population of Tokay geckos has decreased since the installation of new highway lights in the rainforest. Students use their understanding of vision, light, and information processing to figure out why an increase in light in the geckos’ habitat is affecting the population.

An illustration from the Earth's Features unit

3

Environments and Survival

Playing the role of geologists, students help the director of Desert Rocks National Park explain how and when a particular fossil formed and how it came to be in its current location. Students figure out what the environment of the park was like in the past and why it has so many visible rock layers.

An illustration from the Waves, Energy, and Information unit

4

Weather and Climate

In their role as marine scientists, students work to figure out how mother dolphins communicate with their calves. They write a series of scientific explanations with diagrams to demonstrate their growing understanding of how sound waves travel. Then they apply what they’ve learned about waves, energy, and patterns in communication to figure out how to create patterns that can communicate information over distances.

An illustration from the Patterns of Earth and Sky unit

1

Patterns of Earth and Sky

Playing the role of astronomers, students help a team of archaeologists figure out what the missing piece of a recently discovered artifact might have depicted. As they learn about the sun and other stars and the movement of Earth, students can explain what is shown on the artifact and what might be on the missing piece.

An illustration from the Modeling Matter unit

2

Modeling Matter

In their role as food scientists at a fictional company, students are introduced to the idea that all matter is made of particles too small to see, and that each different substance is made of particles (molecules) that are unique. They are then challenged to solve two problems: one requires them to separate a mixture, and the other requires them to make unmixable substances mix. Students are challenged to use the particulate model of matter to explain their work to the CEO of the company.

An illustration from the Earth System unit

3

The Earth System

The cities of East Ferris and West Ferris are located on different sides of a mountain on the fictional Ferris Island. East Ferris is having a water shortage while West Ferris is not. As water resource engineers, students learn about the Earth system to help figure out what is causing the water shortage problem and design possible solutions, including freshwater collection systems and proposals for using chemical reactions to treat wastewater.

An illustration from the Ecosystem Restoration unit

4

Ecosystem Restoration

As ecologists, students work to figure out why the organisms in a part of a Costa Rican rainforest ecosystem aren’t growing and thriving. As they solve this problem, students learn more generally how organisms in an ecosystem get the matter and energy they need to survive, and then write a series of restoration plans that include arguments about why the rainforest ecosystem is not thriving and recommend actions to restore its health.

Print & digital components

Amplify Science California includes instructional guidance and student materials in English and Spanish for a year of instruction, with lessons and activities that keep students engaged every day.

Component

FORMAT

NEW! Classroom Slides

Meet your new hands-free TG! These lesson-specific PowerPoints make delivering daily instruction a snap with embedded links to related resources and suggested teacher talk in the Notes section of each slide.

Digital

Most adopted curriculum for the NGSS California

Teacher’s Reference Guide

Available digitally and in print, this unit-specific reference guide includes scientific background knowledge, planning information and resources, color-coded 3-D Statements, detailed lesson plans, and tips for delivering instruction and differentiating learning.

Print and digital

Two digital devices displaying educational content, one a tablet showing a green-themed start page, and the other a laptop depicting various science chapters.

Hands-on materials kits

Each unit-specific kit contains consumable and nonconsumable materials for use during hands-on investigations. In each kit you will find:

  • Hands-on materials
  • 18 copies of each of the Student Books
  • Big books (grades K–1)
  • Classroom display materials
  • One Student Investigation Notebook

Kit

Amplify Science California supports 3-D learning with more materials than any other program.

NGSS Benchmark Assessments

Delivered four times per year in grades 3–5 and three times per year in grades 6–8, our benchmark assessments report on students’ facility with each of the grade-level appropriate DCIs, SEPs, CCCs, and performance expectations of the California NGSS.

And now, Amplify Science California users can choose to administer the NGSS Benchmark Assessments (grades 3–8) through their Illuminate assessment platform.

*Also available in Spanish

Digital

An open laptop displaying a website with a quiz question about geographical changes over time, featuring a series of island maps from different years.

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.

*Also available in Spanish

Print and digital

Two educational books titled "amplifyscience," one in spanish and one in english, featuring illustrations of desert canyon landscapes on the covers.

Big books (grades K–1)

Amplify Science California never asks our youngest readers to read alone. Rather, we provide scaffolded literacy experiences every step of the way. With our large-format big books, introducing and revisiting concepts though read-aloud and shared reading experiences is a breeze.

*Also available in Spanish

Print

Two hardcover books titled "maravillas rocas" and "rocky wonders" by amplify science, lying open, showing a continuous desert rock formation across both covers.

Simulations and practice tools (grades 2+)

Developed exclusively for the Amplify Science California program, these serve as venues for exploration and data collection, allowing students to explore scientific concepts that might otherwise be invisible or impossible to see with the naked eye.

*Spanish versions coming soon

Digital

A computer screen displays an educational website titled "Earth's Features" with chapters and illustrations of canyons; a printed teacher’s guide is shown beside it.

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Our programs are designed to support and complement one another. Learn more about our related programs.

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Lorem ipsum is placeholder text commonly used in the graphic, print, and publishing industries for previewing layouts and visual mockups.

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Lorem Ipsum

Lorem ipsum is placeholder text commonly used in the graphic, print, and publishing industries for previewing layouts and visual mockups. Lorem ipsum is placeholder text commonly used in the graphic, print, and publishing industries for previewing layouts and visual mockups.

Lorem ipsum is placeholder text commonly used in the graphic, print, and publishing industries for previewing layouts and visual mockups.

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Lorem Ipsum

Lorem ipsum is placeholder text commonly used in the graphic, print, and publishing industries for previewing layouts and visual mockups. Lorem ipsum is placeholder text commonly used in the graphic, print, and publishing industries for previewing layouts and visual mockups.

Lorem ipsum is placeholder text commonly used in the graphic, print, and publishing industries for previewing layouts and visual mockups.

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Lorem Ipsum

Lorem ipsum is placeholder text commonly used in the graphic, print, and publishing industries for previewing layouts and visual mockups. Lorem ipsum is placeholder text commonly used in the graphic, print, and publishing industries for previewing layouts and visual mockups.

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What’s included in our phenomena-based science curriculum

Amplify Science is a phenomena-based science curriculum for grades K-8. This program is designed to give students engaging, realistic experiences that mirror how scientists and engineers actually work. To do this, the Lawrence Hall of Science and Amplify created compelling print and digital resources that work seamlessly together to enable students’ investigations and explorations.

Year at a glance

Amplify Science is organized around units where students are introduced to compelling phenomena and real-world problems, develop and strengthen claims by collecting evidence and testing assumptions, and apply their learning in new contexts.

Un gráfico que muestra secuencias de lecciones de ciencias desde jardín de infantes hasta quinto grado, detallando temas, números de lecciones, días de evaluación y duración de las lecciones para cada grado.

Units at a glance

In each Amplify Science unit, students are asked to inhabit the role of a scientist or engineer in order to investigate a real-world problem. These problems provide relevant, 21st-century contexts through which students investigate different scientific phenomena.

1

Needs of Plants and Animals

Students take on the role of scientists in order to figure out why there have been no monarch caterpillars in the community garden since vegetables were planted. They investigate how plants and animals get what they need to live and grow, and make a new plan for the community garden that provides for the needs of the monarch caterpillars in addition to producing vegetables for humans.

2

Pushes and Pulls

Students take on the role of pinball machine engineers as they investigate the effects of forces on the motion of an object. They conduct tests in their own prototypes (models) of a pinball machine and use what they learn to contribute to the design of a class pinball machine. Over the course of the unit, students construct a foundational understanding of why things move in different ways

Silueta de una estructura de parque infantil contra un cielo azul con nubes y tres soles amarillos.

3

Sunlight and Weather

The principals of Woodland Elementary and Carver Elementary need student weather scientists to help them explain why Woodland’s playground is warmer than Carver’s at recess. Students gather data from models of the sun and Earth’s surface and observe their own playgrounds to figure out how sunlight causes changes in the temperatures of different surfaces. Students then use models to figure out why Woodland’s playground sometimes floods.

1

Animal and Plant Defenses

Students play the role of marine scientists. In their role, students apply their understanding of plant and animal defense structures to explain to aquarium visitors how a sea turtle and her offspring can defend themselves from ocean predators when they are released into the wild.

Dos manos sosteniendo un papel con un dibujo de pirámide y árbol, iluminado por una linterna, proyectando otra sombra de la imagen en la pared.

2

Light and Sound

Students take on the role of light and sound engineers for a puppet show company as they investigate cause and effect relationships to learn about the nature of light and sound. They apply what they learn to design shadow scenery and sound effects for a puppet show.

Ilustración que muestra un paisaje urbano dividido en noche a la izquierda con una luna y estrellas, y día a la derecha con un sol, nubes y un avión.

3

Spinning Earth

As sky scientists, students explain why a boy living in a place near them sees different things in the sky than his grandma does when he talks to her on the phone. Students record, organize, and analyze observations of the sun and other sky objects as they look for patterns and make sense of the cycle of daytime and nighttime.

1

Plant and Animal Relationships

In their role as plant scientists, students work to figure out why there are no new chalta trees growing in the Bengal Tiger Reserve, which is part of a broadleaf forest. Students investigate what the chalta tree needs to survive, then collect and analyze qualitative and quantitative data to solve the mystery.

Una mano sostiene un frijol rojo sobre una mesa, mientras un palo de madera esparce pegamento blanco y frijoles esparcidos. Sobre la mesa también hay una taza blanca y una pluma amarilla.

2

Properties of Materials

As glue engineers, students are challenged to create a glue for use at their school that meets a set of design goals. Students present an evidence-based argument for why their glue mixture will be good for their school to use.

Ilustración de una costa con acantilados, un edificio de centro recreativo con un techo rojo y un letrero, árboles de hoja perenne, una bandera azul y una playa de arena debajo.

3

Changing Landforms

The director of the Oceanside Recreation Center gets a scare when a nearby cliff collapses overnight. Research reveals that the distance between the Recreation Center’s flagpole and the edge of the cliff have changed over time. Students play the role of geologists and work to figure out why the cliff has changed over time. Based on what they learn about erosion, they advise on whether it is safe to keep the center open even though the cliff is changing.

Una ilustración de un tren de alta velocidad moderno y aerodinámico que viaja por una vía elevada con un paisaje verde de fondo.

1

Balancing Forces

People in Faraday are excited to hear that a new train service will be built for their city, but concerned when they hear that it will be a floating train. Students are challenged to figure out how a floating train works in order to explain it to the citizens of Faraday. They develop models of how the train rises, floats, and then falls back to the track, and then write an explanation of how the train works.

Ilustración de una escena de bosque con un oso, un alce, pájaros en una rama y un grupo de lobos en primer plano. Las colinas y los árboles están al fondo bajo un cielo despejado.

2

Inheritance and Traits

Students play the role of wildlife biologists working in Greystone National Park. They study two wolf packs and are challenged to figure out why an adopted wolf (“Wolf 44”) in one of the packs has certain traits. Students observe variation between and within different species, investigate inherited traits and those that result from the environment, and explain the origin of several of the adopted wolf’s traits.

Ilustración de un pájaro mirando un caracol en el suelo, con hojas verdes en el lado izquierdo y un fondo de cielo azul.

3

Environments and Survival

In their role as biomimicry engineers, students work to figure out how the traits of grove snails affect their survival in different environments. They then explore how the traits of different organisms make them more likely or less likely to survive, collecting and interpreting data to understand how organisms’ traits affect their survival in different environments. Students then apply their understanding to a new challenge: designing effective solutions for the removal of invasive plants.

4

Weather and Climate

In their role as meteorologists, students gather evidence to decide where to build an orangutan reserve by analyzing patterns in weather data. After choosing the strongest evidence, students use data to make arguments about which of three fictional islands has weather most like that of orangutans’ existing habitats, Borneo and Sumatra. They then discern patterns in the locations of natural hazards in order to figure out which ones the Wildlife Protection Organization must prepare for.

Ilustración de un paisaje urbano nocturno con ventanas iluminadas y farolas, una luna visible y estrellas en el cielo. Una figura solitaria se recorta en una de las ventanas.

1

Energy Conversions

Students take on the role of systems engineers for Ergstown, a fictional town that experiences frequent blackouts, and explore reasons why an electrical system can fail. Students apply what they learned as they choose new energy sources and energy converters for the town, then write arguments for why their design choices will make the town’s electrical system more reliable.

Un gecko se prepara para atrapar un grillo bajo una farola por la noche. Las flechas amarillas ilustran la luz de la lámpara que golpea al grillo y se refleja en los ojos del gecko.

2

Vision and Light

As conservation biologists, students work to figure out why a population of Tokay geckos has decreased since the installation of new highway lights in the rainforest. Students use their understanding of vision, light, and information processing to figure out why an increase in light in the geckos’ habitat is affecting the population.

3

Earth’s Features

Playing the role of geologists, students help the director of Desert Rocks National Park explain how and when a particular fossil formed and how it came to be in its current location. Students figure out what the environment of the park was like in the past and why it has so many visible rock layers.

Dos delfines nadan bajo el agua en un ambiente teñido de azul, uno frente al otro, y uno parece abrir ligeramente la boca.

4

Waves, Energy, and Information

In their role as marine scientists, students work to figure out how mother dolphins communicate with their calves. They write a series of scientific explanations with diagrams to demonstrate their growing understanding of how sound waves travel. Then they apply what they’ve learned about waves, energy, and patterns in communication to figure out how to create patterns that can communicate information over distances.

1

Patterns of Earth and Sky

Playing the role of astronomers, students help a team of archaeologists figure out what the missing piece of a recently discovered artifact might have depicted. As they learn about the sun and other stars and the movement of Earth, students can explain what is shown on the artifact and what might be on the missing piece.

2

Modeling Matter

In their role as food scientists at a fictional company, students are introduced to the idea that all matter is made of particles too small to see, and that each different substance is made of particles (molecules) that are unique. They are then challenged to solve two problems: one requires them to separate a mixture, and the other requires them to make unmixable substances mix. Students are challenged to use the particulate model of matter to explain their work to the CEO of the company.

Ilustración de un paisaje costero con una montaña y flechas que representan el flujo del viento sobre y alrededor de la montaña, lo que indica la dinámica del flujo de aire.

3

The Earth System

The cities of East Ferris and West Ferris are located on different sides of a mountain on the fictional Ferris Island. East Ferris is having a water shortage while West Ferris is not. As water resource engineers, students learn about the Earth system to help figure out what is causing the water shortage problem and design possible solutions, including freshwater collection systems and proposals for using chemical reactions to treat wastewater.

Ilustración de una escena de la jungla en la que aparecen un guepardo y un perezoso entre un denso follaje verde y varias plantas coloridas.

4

Ecosystem Restoration

As ecologists, students work to figure out why the organisms in a part of a Costa Rican rainforest ecosystem aren’t growing and thriving. As they solve this problem, students learn more generally how organisms in an ecosystem get the matter and energy they need to survive, and then write a series of restoration plans that include arguments about why the rainforest ecosystem is not thriving and recommend actions to restore its health.

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.

Component

Format

Teacher’s Guides

Available digitally and in print, the Teacher’s Guides contain all of the information teachers need to facilitate classroom instruction, including detailed lesson plans, 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

A collection of gardening supplies including a blue bucket, soil bags, plastic cups, hose, fertilizer pellets, and a black tray on a white background.

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

Simulations and practice tools (grades 2+)

Developed exclusively for the Amplify Science program, these serve as venues for exploration and data collection, allowing students to explore scientific concepts that might otherwise be invisible or impossible to see with the naked eye.

Digital

Laptop screen displaying a geographical simulation of a river system with zones: Upper River, Floodplain, and River Delta, including an elevation chart and controls for speed and time adjustment.

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A closer look at grades 6–8

Amplify Science is based on the latest research on teaching and learning and helps teachers deliver rigorous and riveting lessons through hands-on investigations, literacy-rich activities, and interactive digital tools that empower students to think, read, write, and argue like real scientists.

In the 6–8 classroom, this looks like students:

  • Collecting evidence from a variety of sources.
  • Making sense of evidence in a variety of ways.
  • Formulating convincing scientific arguments.

Is your school implementing the domain model? Click here.

Collage of four images showing children engaged in educational activities such as conducting experiments and crafting in a classroom setting.
A four-step process diagram: Spark intrigue, Explore evidence, Explain and elaborate, and Evaluate claims, connected by arrows, with an engagement statement below.

Program structure

Our cyclical lesson design ensures students receive multiple exposures to concepts through a variety of modalities. As they progress through the lessons within a unit, students build and deepen their understanding, increasing their ability to develop and refine complex explanations of the unit’s phenomenon.

It’s this proven program structure and lesson design that enables Amplify Science to teach less, but achieve more. Rather than asking teachers to wade through unnecessary content, we designed our 6–8 program to address 100% of the NGSS in fewer lessons than other programs.

Scope and sequence

Every year our grades 6–8 sequence consists of 9 units, with each unit containing 10–19 lessons. Lessons are written to last a minimum of 45-minutes, though teachers can expand or contract the timing to meet their needs.

A grid of educational icons, each representing a different science topic, such as earth and space science, life science, and physical science, with titles and lesson counts.

Unit types

Each unit delivers three-dimensional learning experiences and engages students in gathering evidence from a rich collection of sources, while also serving a unique purpose.

In grades 6–8, there are three types of units:

  • One unit is a launch unit.
  • Three units are core units.
  • Two units are engineering internships.
Launch units

Launch units are the first units taught in each year of Amplify Science. The goal of the Launch unit is to introduce students to norms, routines, and practices that will be built on throughout the year, including argumentation, active reading, and using the program’s technology. For example, rather than taking the time to explain the process of active reading in every unit in a given year, it is explained thoroughly in the Launch unit, thereby preparing students to read actively in all subsequent units.

Core units

Core units establish the context of the unit by introducing students to a real-world problem. As students move through lessons in a Core unit, they figure out the unit’s anchoring phenomenon, gain an understanding of the unit’s disciplinary core ideas and science and engineering practices, and make linkages across topics through the crosscutting concepts. Each Core unit culminates with a Science Seminar and final writing activity.

Engineering Internship units

Engineering Internship units invite students to design solutions for real-world problems as interns for a fictional company called Futura. Students figure out how to help those in need, from tsunami victims in Sri Lanka to premature babies, through the application of engineering practices. In the process, they apply and deepen their learning from Core units.

Units at a glance

Abstract digital artwork featuring a yellow human figure, red shapes, and a blue-toned screen, with vibrant, multicolored patterns and textures in the background.
Microbiome

Domain: Life Science

Unit type: Launch

Student role: Microbiological researchers

Phenomenon: The presence of 100 trillion microorganisms living on and in the human body may keep the body healthy.  

An abstract illustration of a person receiving an oral examination, with colorful geometric shapes and an eye chart in the background.
Metabolism

Domain: Life Science

Unit type: Core

Student role: Medical researchers

Phenomenon: Elisa, a young patient, feels tired all the time.  

Abstract orange background with geometric shapes, featuring icons of a vest, bar chart, leaf, beaker, fruit, medical stethoscope, and an envelope within a hexagonal frame.
Metabolism Engineering Internship

Domains: Life Science, Engineering Design

Unit type: Engineering internship

Student role: Food engineers

Phenomenon: Designing health bars with different molecular compositions can effectively meet the metabolic needs of patients or rescue workers.  

Six spiders with varying body colors (brown, yellow, blue, and red) and patterns are arranged on a dark, textured background, seemingly in a diagram or chart formation.
Traits and Reproduction

Domain: Life Science

Unit type: Core

Student role: Biomedical students

Phenomenon: Darwin’s bark spider offspring have different silk flexibility traits, even though they have the same parents.  

Illustration of a person with closed eyes in a red winter coat and hat, surrounded by falling snow and orange circles on a dark background.
Thermal Energy

Domain: Physical Science

Unit type: Core

Student role: Thermal scientists

Phenomenon: One of two proposed heating systems for Riverdale School will best heat the school. 

Abstract illustration of a sun with blue and orange rays over a colorful landscape featuring green hills and a vibrant sky.
Ocean, Atmosphere, and Climate

Domains: Earth and Space Science, Physical Science

Unit type: Core

Student role: Climatologists

Phenomenon: During El Niño years, the air temperature in Christchurch, New Zealand is cooler than usual.  

Illustration of clouds above a small town and farmland, with wind currents depicted swirling through the landscape under a blue sky.
Weather Patterns

Domains: Earth and Space Science, Physical Science

Unit type: Core

Student role: Forensic meteorologists

Phenomenon: In recent years, rainstorms in Galetown have been unusually severe.  

A polar bear stands on a small floating ice sheet in the ocean, surrounded by melting ice, with a red sun in the sky.
Earth’s Changing Climate

Domains: Earth and Space Science, Life Science

Unit type: Core

Student role: Climatologists

Phenomenon: The ice on Earth’s surface is melting.  

A purple hexagonal graphic with icons including a building, wrench, screwdriver, sun, molecules, paint bucket, and tiles on a geometric patterned background.
Earth’s Changing Climate Engineering Internship

Domains: Earth and Space Science, Engineering Design

Unit type: Engineering internship

Student role: Civil engineers

Phenomenon: Designing rooftops with different modifications can reduce a city’s impact on climate change.  

A robotic rover sits on a hill in a rocky, reddish landscape, with visible tracks in the dust leading to its current position under a hazy sky.
Geology on Mars

Domain: Earth and Space Science

Unit type: Launch

Student role: Planetary geologists

Phenomenon: Analyzing data about landforms on Mars can provide evidence that Mars may have once been habitable. 

Two green prehistoric reptiles with long snouts are near the shore; one is on land while the other swims in blue water, with plants, rocks, and an island in the background.
Plate Motion

Domain: Earth and Space Science

Unit type: Core

Student role: Geologists

Phenomenon: Mesosaurus fossils have been found on continents separated by thousands of kilometers of ocean, even though the Mesosaurus species once lived all together.  

A purple geometric background featuring a hexagonal badge with a telescope, mountain, audio wave, and star symbols inside.
Plate Motion Engineering Internship

Domains: Earth and Space Science, Engineering Design

Unit type: Engineering internship

Student role: Mechanical engineering interns

Phenomenon: Patterns in earthquake data can be used to design an effective tsunami warning system.  

Illustration showing an ocean, forest, and mountains with a smoking volcano, plus a cross-section of underground tectonic plates.
Rock Transformations

Domain: Earth and Space Science

Unit type: Core

Student role: Geologists

Phenomenon: Rock samples from the Great Plains and from the Rocky Mountains — regions hundreds of miles apart — look very different, but have surprisingly similar mineral compositions.  

Four stages of an orange popsicle melting on a stick, from fully frozen on the left to completely melted on the right, against a plain background.
Phase Change

Domains: Physical Science, Earth and Space Science

Unit type: Core

Student role: Chemists

Phenomenon: A methane lake on Titan no longer appears in images taken by a space probe two years apart

Green geometric background with an outlined hexagon containing icons: a parachute, ruler, letter "A," bandage, stacked blocks, and a folded corner paper.
Force and Motion Engineering Internship

Domains: Engineering Design, Physical Science

Unit type: Engineering internship

Student role: Chemical engineering interns

Phenomenon: Designing portable baby incubators with different combinations of phase change materials can keep babies at a healthy temperature. Domains: Engineering Design, Physical Science

Abstract illustration showing red and blue circles on a split blue and light background, representing molecular movement across a membrane or barrier.
Chemical Reactions

Domains: Physical Science, Life Science, Earth and Space Science

Unit type: Core

Student role: Forensic chemists

Phenomenon: A mysterious brown substance has been detected in the tap water of Westfield.  

An underwater scene with a large whale surrounded by turtles, jellyfish, and various fish swimming in different directions.
Populations and Resources

Domains: Life Science, Earth and Space Science

Unit type: Core

Student role: Biologists

Phenomenon: The size of the moon jelly population in Glacier Sea has increased. 

Low-poly digital illustration of a fox hunting a rabbit in a forest with pine trees, mushrooms, mountains, and the sun in the background. Another rabbit sits near the trees.
Matter and Energy in Ecosystems

Domains: Life Science, Earth and Space Science, Physical Science

Unit type: Core

Student role: Ecologists

Phenomenon: The biodome ecosystem has collapsed.  

Two people climb over rocks filled with electronic devices; inset illustrations show a boot, a belt of batteries, and a radio.
Harnessing Human Energy

Domains: Physical Science, Earth and Space Science, Engineering Design

Unit type: Launch

Student role: Energy scientists

Phenomenon: Rescue workers can use their own human kinetic energy to power the electrical devices they use during rescue missions.  

A spacecraft approaches and docks with a modular space station featuring large blue solar panels, set against a black space background.
Force and Motion

Domain: Physical Science

Unit type: Core

Student role: Physicists

Phenomenon: The asteroid sample-collecting pod failed to dock at the space station as planned.

Green graphic with hexagonal emblem showing an infant, a thermometer, layered materials, a medical symbol, and a flame icon.
Force and Motion Engineering Internship

Domains: Engineering Design, Physical Science

Unit type: Engineering internship

Student role: Chemical engineering interns

Phenomenon: Designing emergency supply delivery pods with different structures can maintain the integrity of the supply pods and their contents.

Illustration of a roller coaster car with passengers raising their arms as they descend a steep track against a blue sky with clouds.
Magnetic Fields

Domain: Physical Science

Unit type: Core

Student role: Physicists

Phenomenon: During a test launch, a spacecraft traveled much faster than expected.  

Illustration of the Earth with arrows representing radiation or energy entering the atmosphere from space, focused on the Asia-Pacific region.
Light Waves

Domains: Physical Science, Life Science, Earth and Space Science

Unit type: Core

Student role: Spectroscopists

Phenomenon: The rate of skin cancer is higher in Australia than in other parts of the world.

A city skyline at night with illuminated windows, a large full moon, stars in the sky, and a bridge visible on the left side.
Earth, Moon, and Sun

Domains: Earth and Space Science, Physical Science

Unit type: Core

Student role: Astronomers

Phenomenon: An astrophotographer can only take pictures of specific features on the Moon at certain times.  

Four polygonal dinosaurs walking in a row, three green and one yellow, each with a rock and purple spikes on their backs, set against a grassy background with a blue sky.
Natural Selection

Domains: Life Science, Earth and Space Science

Unit type: Core

Student role: Biologists

Phenomenon: The newt population in Oregon State Park has become more poisonous over time.  

Red geometric background featuring a hexagonal emblem with icons of a world map, mosquito, DNA strand, bar chart, and interconnected blocks.
Natural Selection Engineering Internship

Domains: Engineering Design, Life Science

Unit type: Engineering internship

Student role: Clinical engineers

Phenomenon: Designing malaria treatment plans that use different combinations of drugs can reduce drug resistance development while helping malaria patients.  

Two tortoises with long necks are by a river; one is browsing leaves from a bush while the other is walking near the water's edge.
Evolutionary History

Domains: Life Science, Earth and Space Science

Unit type: Core

Student role: Paleontologists

Phenomenon: A mystery fossil at the Natural History Museum has similarities with both wolves and whales.    

Resources

Pilot support brochure for 6–8 (Integrated)

Unit phenomena for 6–8

Take a closer look at the unit phenomena featured in each grade level.

Classroom Slides for 6–8

Your new hands-free TG is coming soon! These PowerPoints for every lesson make t…

What’s so phenomenal about phenomena?

Learn actionable strategies that will help you implement 3-D teaching and learni…

Active reading in 6–8

Scientists read and write with purpose too.

Investigations for 6–8

Explore the types of investigations that take place in middle school classrooms….

A laptop screen displaying a map with three ecosystem options, each illustrated by different animal icons and accompanied by relevant data lists.

Sims for 4–8

Approaches to assessment in 6–8

Learn about our middle school embedded assessments.

New Mexico Educators: Welcome to Amplify Science 6–8!

Amplify Science is an engaging core curriculum designed for three-dimensional, phenomena-based learning that is rated ‘all green’ on EdReports.  

With Amplify Science, New Mexico students don’t just passively learn about science concepts. Instead, they take on the role of scientists and engineers to actively investigate and figure out real-world phenomena. They do this through a blend of cohesive and compelling storylines, hands-on investigations, collaborative discussions, literacy-rich activities, and interactive digital tools.

Students conduct science experiments using lab equipment, flashlights, and prisms. The EdReports logo and "Review Year 2020" are also shown.

Amplify Science Success Story

The Lawrence Hall of Science

Developed by the science education experts at UC Berkeley’s Lawrence Hall of Science and the digital learning team at Amplify, our program features:

  • phenomena-based approach where students construct a complex understanding of each unit’s anchor phenomenon.
  • A blend of cohesive storylines, hands-on investigations, rich discussions, literacy-rich activities, and digital tools.
  • Carefully crafted units, chapters, lessons, and activities designed to deliver true 3-dimensional learning.
  • An instructional design that supports all learners in accessing all standards.
Aerial view of the lawrence hall of science at the university of california, berkeley, showcasing the building and surrounding trees with a foggy city backdrop.

Instructional model

The Amplify Science program is rooted in the proven, research-based pedagogy of Do, Talk, Read, Write, Visualize. Here’s how each element works:

Do

First-hand investigations are an important part of any science classroom, and Amplify Science has students getting hands-on in every unit—from building models of protein molecules to experimenting with electrical systems.

Talk

Student-to-student discourse and full-class discussions are an integral part of the program. Students are provided with numerous opportunities to engage in meaningful oral scientific argumentation, all while fostering a collaborative classroom environment.

Read

Students read scientific articles, focusing their reading activities on searching for evidence related to their investigation and, importantly, on asking and recording questions as they read through fascinating texts on 21st-century topics.

Write

Following real-world practices, students write scientific arguments based on evidence they’ve collected, making clear their reasoning about how a given piece of evidence connects to one of several claims.

Visualize

By manipulating digital simulations and using modeling tools to craft visualizations of their thinking— just as real scientists and engineers do—students take their learning far beyond the confines of what they can physically see in the classroom in an exciting and authentic way.

Program structure

Our cyclical lesson design ensures students receive multiple exposures to concepts through a variety of modalities. As they progress through the lessons within a unit, students build and deepen their understanding, increasing their ability to develop and refine complex explanations of the unit’s phenomenon.

It’s this proven program structure and lesson design that enables Amplify Science to address 100% of the NGSS and support students in mastering the New Mexico STEM Ready! Science Standards.

Flowchart depicting a critical thinking process with four circular nodes connected by arrows, each node representing a step: posing a real-world problem, exploring evidence, elaborating concepts, and evaluating claims.

Unit types

While every unit delivers three-dimensional learning experiences and engages students in gathering evidence from a rich collection of sources, each unit also serves a unique instructional purpose.

In grades 6–8:

  • One unit is a launch unit.
  • Three units are core units.
  • Two units are engineering internships.

Launch units are the first units taught in each year of Amplify Science. The goal of the Launch unit is to introduce students to norms, routines, and practices that will be built on throughout the year, including argumentation, active reading, and using the program’s technology. For example, rather than taking the time to explain the process of active reading in every unit in a given year, it is explained thoroughly in the Launch unit, thereby preparing students to read actively in all subsequent units.

Core units establish the context of the unit by introducing students to a real-world problem. As students move through lessons in a Core unit, they figure out the unit’s anchoring phenomenon, gain an understanding of the unit’s disciplinary core ideas and science and engineering practices, and make linkages across topics through the crosscutting concepts. Each Core unit culminates with a Science Seminar and final writing activity.

Engineering Internship units invite students to design solutions for real-world problems as interns for a fictional company called Futura. Students figure out how to help those in need, from tsunami victims in Sri Lanka to premature babies, through the application of engineering practices. In the process, they apply and deepen their learning from Core units.

Unit sequence

Our lessons follow a structure that is grounded in regular routines while still being flexible enough to allow for a variety of learning experiences.

In fact, our multi-modal instruction offers more opportunities for students to construct meaning, and practice and apply concepts than any other program. What’s more, our modular design means our units can be flexibly arranged to support your instructional goals.

Program components

Available digitally and in print, our unit-specific reference guides are chock full of helpful resources, including scientific background knowledge, planning information and resources, color-coded 3-D Statements, detailed lesson plans, tips for delivering instruction, and differentiation strategies.

Amplify Science TG

Hands-on learning is an essential part of Amplify Science, and is integrated into every unit. Students actively participate in science, playing the roles of scientists and engineers as they gather evidence, think critically, solve problems, and develop and defend claims about the world around them. Every unit includes hands-on investigations that are critical to achieving the unit’s learning goals.

Amplify Science Flextension

More hands-on with Flextensions:
Hands-on Flextensions are additional, optional investigations that are included at logical points in the learning progression and give students an opportunity to dig deeper if time permits. These activities offer teachers flexibility to choose to dedicate more time to hands-on learning. Materials referenced in Hands-on Flextension activities will either be included in the unit kit or are easily sourced. Supporting resources such as student worksheets will be included as downloadable PDF files.

Our kits include enough materials to support 200 student uses. In other words, teachers can easily support all five periods and small groups of 4-5 students each. Plus, our unit-specific kits mean teachers just grab the tub they need and then put it all back with ease.

Middle School Materials Kit List 

Assorted office and household items displayed on a white background, including rubber bands, binder clips, cardboard, and sports balls.

Our digital Simulations and Practice Tools are powerful resources for exploration, data collection, and student collaboration. They allow students the ability to explore scientific concepts that might otherwise be invisible or impossible to see with the naked eye.

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

In grades 6–8, one copy of the Student Investigation Notebook is included in each unit’s materials kit for use as a blackline master. Each notebook is also available as a downloadable PDF on the Unit Guide page of the digital Teacher’s Guide.

Amplify Science Student Investigation Notebooks

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.

Amplify Science Classroom Slides

Full coverage of NGSS and New Mexico STEM Ready! Science Standards

Amplify Science was designed from the ground up to meet the Next Generation Science Standards (NGSS). As such, it aligns to the New Mexico Science Standards, which were also borne out of the NGSS.

K-8 NGSS Correlation by Dimension

K-8 NM STEM Ready! Standards Correlation

Explore your print samples

With your Amplify Science print samples, you’ll find unit-specific Teacher’s References Guides and Student Investigation Notebooks for each grade level.

A note about the Teacher’s Reference Guides:

It’s important that your committee sees the full breadth and depth of our instruction. For that reason, we provided a copy of each of our unit-specific Teacher Reference Guides.

Rest assured that teachers do not use these robust reference guides for day-to-day teaching. For that, we have a hands-free Teacher Guide!

A laptop screen displays a simulation of energy arrows entering and exiting Earth's system, flanked by diagrams explaining water flow and an energy token model.
  • Teacher Reference Guide: Unlike a typical Teacher Guide that requires a series of supplemental books to support it, our encyclopedic reference guide is chock-full of everything a teacher needs to fully implement our program and the NGSS.
  • Ready-to-Teach Lesson Slides: For daily instruction, teachers need their hands free. That’s why we created ready-to-teach lesson slides for every single lesson. What’s more, they are editable and include suggested teacher talk and point-of-use differentiation and other instructional tips. Click to learn more.

A note about the Materials Kits:

Hands-on learning is at the heart of Amplify Science, and is integrated into every unit. In order to make hands-on learning more manageable for busy teachers, Amplify Science materials are organized into unit-specific kits.

Stacked storage bins with labels, arranged neatly; caption notes they are a sample and may not reflect actual quantities or sizes.

Our unit-specific kits:

  • Include more materials — We give teachers enough materials to support 200 student uses.
  • Are more manageable — Unlike other programs that require large groups of students to share limited sets of materials, our kits include enough to support small groups of 4–5 students.
  • Include supportive videos — Each hands-on activity provides clear instructions for the teacher, with more complex activities supported by video demonstrations and illustrations.

Materials Kit List

Access your digital samples

Explore as a teacher

Follow these instructions to explore the Amplify Science digital platform as a teacher.

  • Click the Access Amplify Science Platform button below and bookmark it.
  • Select Log in with Amplify.
  • Enter the username: t20.sci6-8@tryamplify.net
  • Enter the password: AmplifyNumber1
  • Click on Science in Your Programs
  • Click on the Program drop-down menu and select your desired domain
  • Select any unit.
Access Amplify Science Platform

To help familiarize yourself with navigating the digital platform, watch the below navigational video.

Explore as a student

Follow these instructions to explore the Amplify Science digital platform as a student.

  • Click the Access Amplify Science Platform button below and bookmark it.
  • Select Log in with Amplify.
  • Enter the username: s20.sci6-8@tryamplify.net
  • Enter the password: AmplifyNumber1
  • Click Science in Your Programs
  • Click on the Program drop-down menu and select your desired domain
  • Select any unit title.
Access Amplify Science Platform

Additional resources to support your review

Welcome to Amplify Science 6–8!

Amplify Science is an engaging core curriculum designed for three-dimensional, phenomena-based learning.

With Amplify Science, Detroit students don’t just passively learn about science concepts. Instead, they take on the role of scientists and engineers to actively investigate and figure out real-world phenomena. They do this through a blend of cohesive and compelling storylines, hands-on investigations, collaborative discussions, literacy-rich activities, and interactive digital tools.

What is Amplify Science?

The Lawrence Hall of Science

Developed by the science education experts at UC Berkeley’s Lawrence Hall of Science and the digital learning team at Amplify, our program features:

  • phenomena-based approach where students construct a complex understanding of each unit’s anchor phenomenon.
  • A blend of cohesive storylines, hands-on investigations, rich discussions, literacy-rich activities, and digital tools.
  • Carefully crafted units, chapters, lessons, and activities designed to deliver true three-dimensional learning.
  • An instructional design that supports all learners in accessing all standards.

Proven to work

WestEd Randomized
Control Trial for Grade 1

Read More

WestEd Randomized
Control Trial for Grade 7

Read More

Amplify Science NE
Grades K–5

Read More

Instructional model

The Amplify Science program is rooted in the proven, research-based pedagogy of Do, Talk, Read, Write, Visualize. Here’s how each element works:

Do

First-hand investigations are an important part of any science classroom, and Amplify Science has students getting hands-on in every unit—from building models of protein molecules to experimenting with electrical systems.

Talk

Student-to-student discourse and full-class discussions are an integral part of the program. Students are provided with numerous opportunities to engage in meaningful oral scientific argumentation, all while fostering a collaborative classroom environment.

Read

Students read scientific articles, focusing their reading activities on searching for evidence related to their investigation and, importantly, on asking and recording questions as they read through fascinating texts on 21st-century topics.

Write

Following real-world practices, students write scientific arguments based on evidence they’ve collected, making clear their reasoning about how a given piece of evidence connects to one of several claims.

Visualize

By manipulating digital simulations and using modeling tools to craft visualizations of their thinking— just as real scientists and engineers
do—students take their learning far beyond the confines of what they can physically see in the classroom in an exciting and authentic way.

Program structure

Our cyclical lesson design ensures students receive multiple exposures to concepts through a variety of modalities. As they progress through the lessons within a unit, students build and deepen their understanding, increasing their ability to develop and refine complex explanations of the unit’s phenomenon.

It’s this proven program structure and lesson design that enables Amplify Science to address 100% of the Next Generation Science Standards (NGSS) and support students in mastering the Pennsylvania Science Standards.

Flowchart depicting a critical thinking process with four circular nodes connected by arrows, each node representing a step: posing a real-world problem, exploring evidence, elaborating concepts, and evaluating claims.

Unit types

While every unit delivers three-dimensional learning experiences and engages students in gathering evidence from a rich collection of sources, each unit also serves a unique instructional purpose.

In grades 6–8:

  • One unit is a launch unit.
  • Three units are core units.
  • Two units are engineering internships.

Launch units are the first units taught in each year of Amplify Science. The goal of the Launch unit is to introduce students to norms, routines, and practices that will be built on throughout the year, including argumentation, active reading, and using the program’s technology. For example, rather than taking the time to explain the process of active reading in every unit in a given year, it is explained thoroughly in the Launch unit, thereby preparing students to read actively in all subsequent units.

Core units establish the context of the unit by introducing students to a real-world problem. As students move through lessons in a Core unit, they figure out the unit’s anchoring phenomenon, gain an understanding of the unit’s disciplinary core ideas and science and engineering practices, and make linkages across topics through the crosscutting concepts. Each Core unit culminates with a Science Seminar and final writing activity.

Engineering Internship units invite students to design solutions for real-world problems as interns for a fictional company called Futura. Students figure out how to help those in need, from tsunami victims in Sri Lanka to premature babies, through the application of engineering practices. In the process, they apply and deepen their learning from Core units.

Unit sequence

Our lessons follow a structure that is grounded in regular routines while still being flexible enough to allow for a variety of learning experiences.

In fact, our multi-modal instruction offers more opportunities for students to construct meaning, and practice and apply concepts than any other program. What’s more, our modular design means our units can be flexibly arranged to support your instructional goals.

Three columns listing education curriculum topics for grades 6, 7, and 8, focusing on science themes such as microbiomes, mars geology, and harnessing human energy.

Program components

Available digitally and in print, our unit-specific reference guides are chock-full of helpful resources, including scientific background knowledge, planning information and resources, color-coded 3D Statements, detailed lesson plans, tips for delivering instruction, and differentiation strategies.

Amplify Science TG

Hands-on learning is an essential part of Amplify Science, and is integrated into every unit. Students actively participate in science, playing the roles of scientists and engineers as they gather evidence, think critically, solve problems, and develop and defend claims about the world around them. Every unit includes hands-on investigations that are critical to achieving the unit’s learning goals.

A young person wearing gloves looks through a microscope at a table with laboratory supplies, including bottles, slides, and a tray, against a plain blue background.

More hands-on with Flextensions:
Hands-on Flextensions are additional, optional investigations that are included at logical points in the learning progression and give students an opportunity to dig deeper if time permits. These activities offer teachers flexibility to choose to dedicate more time to hands-on learning. Materials referenced in Hands-on Flextension activities will either be included in the unit kit or are easily sourced. Supporting resources such as student worksheets will be included as downloadable PDF files.

Our kits include enough materials to support 200 student uses. In other words, teachers can easily support all five periods and small groups of 4-5 students each. Plus, our unit-specific kits mean teachers just grab the tub they need and then put it all back with ease.

Assorted office and household items displayed on a white background, including rubber bands, binder clips, cardboard, and sports balls.

Our digital Simulations and Practice Tools are powerful resources for exploration, data collection, and student collaboration. They allow students the ability to explore scientific concepts that might otherwise be invisible or impossible to see with the naked eye.

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

In grades 6–8, one copy of the Student Investigation Notebook is included in each unit’s materials kit for use as a blackline master. Each notebook is also available as a downloadable PDF on the Unit Guide page of the digital Teacher’s Guide.

Two booklets titled "El clima cambiante de la Tierra: la desaparición del hielo" and "Earth’s Changing Climate: Vanishing Ice" with landscape illustrations on the covers.

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.

Amplify Science Classroom Slides

Explore your print samples

With your Amplify Science print samples, you’ll find unit-specific Teacher’s References Guides and Student Investigation Notebooks for each grade level.

A note about the Teacher’s Reference Guides:

It’s important that your committee sees the full breadth and depth of our instruction. For that reason, we provided a copy of each of our unit-specific Teacher Reference Guides.

Rest assured that teachers do not use these robust reference guides for day-to-day teaching. For that, we have a hands-free TG!

Three laptop screens displaying educational content on earth's energy system, including diagrams and text annotations.
  • Teacher Reference Guide: Unlike a typical TG that requires a series of supplemental books to support it, our encyclopedic reference guide is chock-full of everything a teacher needs to fully implement our program and the NGSS.
  • Ready-to-Teach Lesson Slides: For daily instruction, teachers need their hands free. That’s why we created ready-to-teach lesson slides for every single lesson. What’s more, they are editable and include suggested teacher talk and point-of-use differentiation and other instructional tips. Click to learn more.

A note about the Materials Kits:

Hands-on learning is at the heart of Amplify Science, and is integrated into every unit. In order to make hands-on learning more manageable for busy teachers, Amplify Science materials are organized into unit-specific kits.

Stacked storage bins with labels, arranged neatly; caption notes they are a sample and may not reflect actual quantities or sizes.

Our unit-specific kits:

  • Include more materials — We give teachers enough materials to support 200 student uses.
  • Are more manageable — Unlike other programs that require large groups of students to share limited sets of materials, our kits include enough to support small groups of 4–5 students.
  • Include supportive videos — Each hands-on activity provides clear instructions for the teacher, with more complex activities supported by video demonstrations and illustrations.

At your request, we did not include our materials kits with our submissions samples. However, we did provide grade-specific lists of all materials included in each kit, which you can also find with the links below.

Access your digital samples

Explore as a teacher

Follow these instructions to explore the Amplify Science digital platform as a teacher.

  • Click the Access Amplify Science Platform button below and bookmark it.
  • Select Log in with Amplify.
  • Enter the username: t1.dps68sci@demo.tryamplify.net
  • Enter the password: Amplify1-dps68sci
  • Click the Science icon.
  • Click on the Grade Menu in the top center of the screen and select any grade.
  • Select any unit.
Access Amplify Science Platform

To help familiarize yourself with navigating the digital platform, watch the below navigational video.

Spanish-language support

Amplify Science is committed to providing support to meet the needs of all learners, including multiple access points for Spanish-speaking students. Developed in conjunction with Spanish-language experts and classroom teachers, several components are available in Spanish across the Amplify Science curriculum.

Spanish-language materials include:

COMPONENTTEACHER/STUDENT
Student Investigation NotebooksStudent
Science articlesStudent
Video TranscriptsStudent
Digital simulation translation keysStudent
Printed classroom materials
Unit and chapter questions, key concepts, vocabulary cards, etc.		Teacher
CopymastersTeacher
AssessmentsTeacher
Digital student experience license
This license gives students access to the student resources in Spanish, including instructional text, articles, and assessments. Teachers can control student access to Spanish-language content through the digital Teacher’s Guide.		Teacher
Spanish teacher support license
This license includes teacher talk, projections, downloadable PDFs of all print resources, and video transcripts and closed captioning in Spanish.		Teacher

Explore as a student

Follow these instructions to explore the Amplify Science digital platform as a student.

  • Click the Access Amplify Science Platform button below and bookmark it.
  • Select Log in with Amplify.
  • Enter the username: s1.dpsscience@demo.tryamplify.net
  • Enter the password: Amplify1-dpsscience
  • Click the Science icon.
  • Click on the Grade Menu in the top center of the screen and select any grade.
  • Select any unit.
Access Amplify Science Platform

Resources to support your review

What’s New for Amplify Science 6–8!

Denver Public Schools (DPS), check out what’s new from Amplify Science 6-8!  The first part of this site will take you through the updates that have been made to Amplify Science. The second will be a refresher of Amplify Science for any new users in DPS. With Amplify Science, DPS students don’t just passively learn about science concepts. Instead, they take on the role of scientists and engineers to actively investigate and figure out real-world phenomena. With culturally sustaining pedagogy, Amplify Science strives to make sure every student feels included in the science classroom.

Two students collaborating on a project using a laptop in a classroom filled with other students working in the background.

Update: The Digital Experience

The digital experience allows students to engage with digital lessons and provides teachers with everything they need in one place—ready-to-use slides-based lessons, seamlessly integrated teacher prompts and guidance, robust PD resources, and more. It’s now easier and more engaging than ever to plan lessons, present digital content, and review student work. To learn more, click here.

Update: The PD Library

All professional development (PD) content is consolidated into the PD Library, a one-stop hub for all your self-paced PD needs. As a result, the “Professional Learning Resources” tile will no longer be available on the main Amplify Science Program Hub page. The rest of the non-PD content in the Program Hub will remain as is, including the on-demand resources.

Update: Educator & Student Home expansion

Educator and Student Home landing pages will now be available for all Amplify Science users. This Home page provides a central location to access all Amplify programs in one place and a customized stream based on your activity.

Your Amplify Science grades 6–8 students will no longer access My Work for assignments, scores, and teacher feedback. Instead, they’ll find it all on Student Home, the page they already land on when logging in to Amplify Science.

Keep in mind: Amplify Science middle school teachers will continue to have access to Classwork.

Update: Caregiver Hub

Throughout the school year, teachers can share the Amplify Science Caregiver Hub with students’ families. This site provides curriculum details, an overview of what caregivers can expect throughout the school year, and resources they can use with students at home.

What is Amplify Science?

The Lawrence Hall of Science

Developed by the science education experts at UC Berkeley’s Lawrence Hall of Science and the digital learning team at Amplify, our program features:

  • phenomena-based approach where students construct a complex understanding of each unit’s anchor phenomenon.
  • A blend of cohesive storylines, hands-on investigations, rich discussions, literacy-rich activities, and digital tools.
  • Carefully crafted units, chapters, lessons, and activities designed to deliver true three-dimensional learning.
  • An instructional design that supports all learners in accessing all standards.
Aerial view of the lawrence hall of science at the university of california, berkeley, showcasing the building and surrounding trees with a foggy city backdrop.

Proven to work

WestEd Randomized
Control Trial for Grade 1

Read More

WestEd Randomized
Control Trial for Grade 7

Read More

Amplify Science NE
Grades K–5

Read More

Instructional model

The Amplify Science program is rooted in the proven, research-based pedagogy of Do, Talk, Read, Write, Visualize. Here’s how each element works:

Do

First-hand investigations are an important part of any science classroom, and Amplify Science has students getting hands-on in every unit—from building models of protein molecules to experimenting with electrical systems.

Talk

Student-to-student discourse and full-class discussions are an integral part of the program. Students are provided with numerous opportunities to engage in meaningful oral scientific argumentation, all while fostering a collaborative classroom environment.

Read

Students read scientific articles, focusing their reading activities on searching for evidence related to their investigation and, importantly, on asking and recording questions as they read through fascinating texts on 21st-century topics.

Write

Following real-world practices, students write scientific arguments based on evidence they’ve collected, making clear their reasoning about how a given piece of evidence connects to one of several claims.

Visualize

By manipulating digital simulations and using modeling tools to craft visualizations of their thinking— just as real scientists and engineers
do—students take their learning far beyond the confines of what they can physically see in the classroom in an exciting and authentic way.

Program structure

Our cyclical lesson design ensures students receive multiple exposures to concepts through a variety of modalities. As they progress through the lessons within a unit, students build and deepen their understanding, increasing their ability to develop and refine complex explanations of the unit’s phenomenon.

It’s this proven program structure and lesson design that enables Amplify Science to address 100% of the Next Generation Science Standards (NGSS) and support students in mastering the Pennsylvania Science Standards.

Flowchart depicting a critical thinking process with four circular nodes connected by arrows, each node representing a step: posing a real-world problem, exploring evidence, elaborating concepts, and evaluating claims.

Unit types

While every unit delivers three-dimensional learning experiences and engages students in gathering evidence from a rich collection of sources, each unit also serves a unique instructional purpose.

In grades 6–8:

  • One unit is a launch unit.
  • Three units are core units.
  • Two units are engineering internships.

Launch units are the first units taught in each year of Amplify Science. The goal of the Launch unit is to introduce students to norms, routines, and practices that will be built on throughout the year, including argumentation, active reading, and using the program’s technology. For example, rather than taking the time to explain the process of active reading in every unit in a given year, it is explained thoroughly in the Launch unit, thereby preparing students to read actively in all subsequent units.

Core units establish the context of the unit by introducing students to a real-world problem. As students move through lessons in a Core unit, they figure out the unit’s anchoring phenomenon, gain an understanding of the unit’s disciplinary core ideas and science and engineering practices, and make linkages across topics through the crosscutting concepts. Each Core unit culminates with a Science Seminar and final writing activity.

Engineering Internship units invite students to design solutions for real-world problems as interns for a fictional company called Futura. Students figure out how to help those in need, from tsunami victims in Sri Lanka to premature babies, through the application of engineering practices. In the process, they apply and deepen their learning from Core units.

DPS Scope and Sequence

Our lessons follow a structure that is grounded in regular routines while still being flexible enough to allow for a variety of learning experiences.

In fact, our multi-modal instruction offers more opportunities for students to construct meaning, and practice and apply concepts than any other program. What’s more, our modular design means our units can be flexibly arranged to support your instructional goals.

Un gráfico que muestra los cursos de ciencias para los grados 6 a 8. Cada grado tiene una lista de clases categorizadas como Launch, GROW y GOAT, con el título de cada curso y la duración en minutos o días.

Program components

Available digitally and in print, our unit-specific reference guides are chock-full of helpful resources, including scientific background knowledge, planning information and resources, color-coded 3D Statements, detailed lesson plans, tips for delivering instruction, and differentiation strategies.

Amplify Science TG

Hands-on learning is an essential part of Amplify Science, and is integrated into every unit. Students actively participate in science, playing the roles of scientists and engineers as they gather evidence, think critically, solve problems, and develop and defend claims about the world around them. Every unit includes hands-on investigations that are critical to achieving the unit’s learning goals.

A young person wearing gloves looks through a microscope at a table with laboratory supplies, including bottles, slides, and a tray, against a plain blue background.

More hands-on with Flextensions:
Hands-on Flextensions are additional, optional investigations that are included at logical points in the learning progression and give students an opportunity to dig deeper if time permits. These activities offer teachers flexibility to choose to dedicate more time to hands-on learning. Materials referenced in Hands-on Flextension activities will either be included in the unit kit or are easily sourced. Supporting resources such as student worksheets will be included as downloadable PDF files.

Our kits include enough materials to support 200 student uses. In other words, teachers can easily support all five periods and small groups of 4-5 students each. Plus, our unit-specific kits mean teachers just grab the tub they need and then put it all back with ease.

Assorted office and household items displayed on a white background, including rubber bands, binder clips, cardboard, and sports balls.

Our digital Simulations and Practice Tools are powerful resources for exploration, data collection, and student collaboration. They allow students the ability to explore scientific concepts that might otherwise be invisible or impossible to see with the naked eye.

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

In grades 6–8, one copy of the Student Investigation Notebook is included in each unit’s materials kit for use as a blackline master. Each notebook is also available as a downloadable PDF on the Unit Guide page of the digital Teacher’s Guide.

Two booklets titled "El clima cambiante de la Tierra: la desaparición del hielo" and "Earth’s Changing Climate: Vanishing Ice" with landscape illustrations on the covers.

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.

Amplify Science Classroom Slides

Explore your print samples

With your Amplify Science print samples, you’ll find unit-specific Teacher’s References Guides, Student Investigation Notebooks, and sets of Student Books for each grade level.

A note about the Teacher Reference Guides:

It’s important that you see the full breadth and depth of our instruction. For that reason, we provide a copy of each of our unit-specific Teacher Reference Guides.

Rest assured that teachers do not use these robust reference guides for day-to-day teaching. For that, we have a hands-free Teacher’s Guide!

Three laptop screens displaying educational content on earth's energy system, including diagrams and text annotations.
  • Teacher Reference Guide: Unlike a typical TG that requires a series of supplemental books to support it, our encyclopedic reference guide is chock-full of everything a teacher needs to fully implement our program and the NGSS.
  • Ready-to-Teach Lesson Slides: For daily instruction, teachers need their hands free. That’s why we created ready-to-teach lesson slides for every single lesson. What’s more, they are editable and include suggested teacher talk and point-of-use differentiation and other instructional tips. Click to learn more.

A note about the Materials Kits:

Hands-on learning is at the heart of Amplify Science, and is integrated into every unit. In order to make hands-on learning more manageable for busy teachers, Amplify Science materials are organized into unit-specific kits.

Stacked storage bins with labels, arranged neatly; caption notes they are a sample and may not reflect actual quantities or sizes.

Our unit-specific kits:

  • Include more materials — We give teachers enough materials to support 200 student uses.
  • Are more manageable — Unlike other programs that require large groups of students to share limited sets of materials, our kits include enough to support small groups of 4–5 students.
  • Include supportive videos — Each hands-on activity provides clear instructions for the teacher, with more complex activities supported by video demonstrations and illustrations.

At your request, we did not include our materials kits with our submissions samples. However, we did provide grade-specific lists of all materials included in each kit, which you can also find with the links below.

Access your digital samples

Explore as a teacher

Follow these instructions to explore the Amplify Science digital platform as a teacher.

  • Click the Access Amplify Science Platform button below and bookmark it.
  • Select Log in with Amplify.
  • Enter the username: t1.dps68sci@demo.tryamplify.net
  • Enter the password: Amplify1-dps68sci
  • Click the Science icon.
  • Click on the Grade Menu in the top center of the screen and select any grade.
  • Select any unit.
Access Amplify Science Platform

To help familiarize yourself with navigating the digital platform, watch the below navigational video.

Spanish-language support

Amplify Science is committed to providing support to meet the needs of all learners, including multiple access points for Spanish-speaking students. Developed in conjunction with Spanish-language experts and classroom teachers, several components are available in Spanish across the Amplify Science curriculum.

Spanish-language materials include:

COMPONENTTEACHER/STUDENT
Student Investigation NotebooksStudent
Science articlesStudent
Video TranscriptsStudent
Digital simulation translation keysStudent
Printed classroom materials
Unit and chapter questions, key concepts, vocabulary cards, etc.		Teacher
CopymastersTeacher
AssessmentsTeacher
Digital student experience license
This license gives students access to the student resources in Spanish, including instructional text, articles, and assessments. Teachers can control student access to Spanish-language content through the digital Teacher’s Guide.		Teacher
Spanish teacher support license
This license includes teacher talk, projections, downloadable PDFs of all print resources, and video transcripts and closed captioning in Spanish.		Teacher

Resources to support your review

Contact Us

If you have any further questions as your review Amplify Science, please contact:

Monty Lammers

Senior Account Executive

719-964-4501

mlammers@amplify.com

Welcome to Amplify Science Pennsylvania
(6–8)!

Amplify Science is an engaging core curriculum designed for three-dimensional, phenomena-based learning.

With Amplify Science, Pennsylvania students shift from learning about to figuring out science, through authentic three-dimensional (3D) learning and phenomena-based exploration. In each unit, students take on the role of a scientist or engineer to investigate a real-world problem. This prepares them to become critical thinkers who can solve problems in their communities and beyond.

Review K-5 Science
Two students sit at a classroom table, smiling and working together on a laptop and worksheet, guided by Pennsylvania teachers, with other students in the background.

What is Amplify Science Pennsylvania?

Customized lessons for Pennsylvania

Amplify Science Pennsylvania (6–8) combines our nationally recognized, proven curriculum with custom lessons specifically designed to ensure that you are meeting Pennsylvania’s STEELS standards.

A digital dashboard displays six science lesson tiles, featuring "Designing for Energy Sustainability" in the lower right corner, and supports three-dimensional learning inspired by Amplify Science and PA STEELS standards.

The Lawrence Hall of Science

Developed by the science education experts at UC Berkeley’s Lawrence Hall of Science and the digital learning team at Amplify, our program features:

  • phenomena-based approach, in which students construct a complex understanding of each unit’s anchor phenomenon.
  • A blend of cohesive storylines, hands-on investigations, rich discussions, literacy-rich activities, and digital tools.
  • Carefully crafted units, chapters, lessons, and activities designed to deliver true three-dimensional learning.
  • An instructional design that supports all learners in accessing all standards.
Aerial view of the lawrence hall of science at the university of california, berkeley, showcasing the building and surrounding trees with a foggy city backdrop.

Proven to work

A pdf cover from wested titled "learning and literacy development together: initial results from a curriculum study," featuring an adult helping children with schoolwork in a classroom.

WestEd Randomized
Control Trial for Grade 1

Read More

Pdf cover titled "curriculum materials designed for the next generation science standards: initial results from gold standard research trials", published by wested.

WestEd Randomized
Control Trial for Grade 7

Read More

A teacher and students engage in a science activity around a table. The text promotes the Amplify Science K–8 curriculum, highlighting its focus on hands-on learning and real-world problem-solving.

Amplify Science Pennsylvania NE
Grades K–5

Read More

Instructional model

The Amplify Science Pennsylvania program is rooted in the proven, research-based pedagogy of Do, Talk, Read, Write, Visualize. Here’s how each element works:

Do

First-hand investigations are an important part of any science classroom, and Amplify Science Pennsylvania has students getting hands-on in every unit—from building models of protein molecules to experimenting with electrical systems.

Talk

Student-to-student discourse and full-class discussions are an integral part of the program. Students are provided with numerous opportunities to engage in meaningful oral scientific argumentation while fostering a collaborative classroom environment.

Read

Students read scientific articles, focusing on searching for evidence related to their investigation and on asking and recording questions as they read through fascinating texts on 21st-century topics.

Write

Following real-world practices, students write scientific arguments based on evidence they’ve collected, making clear their reasoning about how a given piece of evidence connects to one of several claims.

Visualize

By manipulating digital simulations and using modeling tools to craft visualizations of their thinking— just as real scientists and engineers
do—students take their learning far beyond the confines of what they can physically see in the classroom in an exciting and authentic way.

Program structure

Our cyclical lesson design ensures that students receive multiple exposures to concepts through a variety of modalities. As they progress through the lessons within a unit, students build and deepen their understanding, increasing their ability to develop and refine complex explanations of the unit’s phenomenon.

It’s this proven program structure and lesson design that enables Amplify Science Pennsylvania to address 100% of the Next Generation Science Standards (NGSS), and support students in mastering the Pennsylvania Science Standards.

Flowchart depicting a critical thinking process with four circular nodes connected by arrows, each node representing a step: posing a real-world problem, exploring evidence, elaborating concepts, and evaluating claims.

Unit types

While every unit delivers three-dimensional learning experiences and engages students in gathering evidence from a rich collection of sources, each unit also serves a unique instructional purpose.

In grades 6–8:

  • One unit is a launch unit.
  • Three units are core units.
  • Two units are engineering internships.

Launch units are the first units taught in each year of Amplify Science Pennsylvania. The goal of the Launch unit is to introduce students to norms, routines, and practices that will be built on throughout the year, including argumentation, active reading, and using the program’s technology. For example, rather than taking the time to explain the process of active reading in every unit in a given year, it is explained thoroughly in the Launch unit, thereby preparing students to read actively in all subsequent units.

Core units establish the context of the unit by introducing students to a real-world problem. As students move through lessons in a Core unit, they figure out the unit’s anchoring phenomenon, gain an understanding of the unit’s disciplinary core ideas and science and engineering practices, and make linkages across topics through the crosscutting concepts. Each Core unit culminates with a Science Seminar and final writing activity.

Engineering Internship units invite students to design solutions for real-world problems as interns for a fictional company called Futura. Students figure out how to help those in need, from tsunami victims in Sri Lanka to premature babies, through the application of engineering practices. In the process, they apply and deepen their learning from Core units.

Unit sequence

Our lessons follow a structure that is grounded in regular routines while still being flexible enough to allow for a variety of learning experiences.

In fact, our multimodal instruction offers more opportunities for students to construct meaning, and practice and apply concepts, than any other program. What’s more, our modular design means our units can be flexibly arranged to support your instructional goals.

Three columns listing education curriculum topics for grades 6, 7, and 8, focusing on science themes such as microbiomes, mars geology, and harnessing human energy.

Program components

Available digitally and in print, our unit-specific reference guides are chock full of helpful resources, including scientific background knowledge, planning information and resources, color-coded 3D Statements, detailed lesson plans, tips for delivering instruction, and differentiation strategies.

Amplify Science TG

Hands-on learning is an essential part of Amplify Science Pennsylvania, and is integrated into every unit. Students actively participate in science, playing the roles of scientists and engineers as they gather evidence, think critically, solve problems, and develop and defend claims about the world around them. Every unit includes hands-on investigations that are critical to achieving the unit’s learning goals.

A young person wearing gloves looks through a microscope at a table with laboratory supplies, including bottles, slides, and a tray, against a plain blue background.

More hands-on with Flextensions:
Hands-on Flextensions are additional, optional investigations that are included at logical points in the learning progression and give students an opportunity to dig deeper if time permits. These activities offer teachers flexibility to choose to dedicate more time to hands-on learning. Materials referenced in Hands-on Flextension activities will either be included in the unit kit or are easily sourced. Supporting resources such as student worksheets will be included as downloadable PDF files.

Our kits include enough materials to support 200 student uses. In other words, teachers can easily support all five periods and small groups of 4–5 students each. Plus, our unit-specific kits mean teachers just grab the tub they need and then put all the materials back with ease.

Assorted office and household items displayed on a white background, including rubber bands, binder clips, cardboard, and sports balls.

Our digital Simulations and Practice Tools are powerful resources for exploration, data collection, and student collaboration. They allow students the ability to explore scientific concepts that might otherwise be invisible or impossible to see with the naked eye.

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

In grades 6–8, one copy of the Student Investigation Notebook is included in each unit’s materials kit for use as a blackline master. Each notebook is also available as a downloadable PDF on the Unit Guide page of the digital Teacher’s Guide.

Two booklets titled "El clima cambiante de la Tierra: la desaparición del hielo" and "Earth’s Changing Climate: Vanishing Ice" with landscape illustrations on the covers.

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.

Amplify Science Classroom Slides

Explore your print samples

With your Amplify Science Pennsylvania print samples, you’ll find unit-specific Teacher’s References Guides and Student Investigation Notebooks for each grade level.

A note about the Teacher Reference Guides:

It’s important that your committee sees the full breadth and depth of our instruction. For that reason, we’ve provided a copy of each of our unit-specific Teacher Reference Guides.

Teachers do not use these robust reference guides for day-to-day teaching. For that, we have a hands-free Teacher’s Guide!

Three laptop screens displaying educational content on earth's energy system, including diagrams and text annotations.
  • Teacher Reference Guide: Unlike a typical Teacher Guide that requires a series of supplemental books to support it, our encyclopedic reference guide is chock-full of everything a teacher needs to fully implement our program and the NGSS.
  • Ready-to-Teach Lesson Slides: For daily instruction, teachers need their hands free. That’s why we created ready-to-teach lesson slides for every single lesson. What’s more, they are editable and include suggested teacher talk and point-of-use differentiation and other instructional tips. Click to learn more.

A note about the Materials Kits:

Hands-on learning is at the heart of Amplify Science Pennsylvania, and is integrated into every unit. In order to make hands-on learning more manageable for busy teachers, Amplify Science Pennsylvania materials are organized into unit-specific kits.

Stacked storage bins with labels, arranged neatly; caption notes they are a sample and may not reflect actual quantities or sizes.

Our unit-specific kits:

  • Include more materials. We give teachers enough materials to support 200 student uses.
  • Are more manageable. Unlike other programs that require large groups of students to share limited sets of materials, our kits include enough to support small groups of four to five students.
  • Include supportive videos. Each hands-on activity provides clear instructions for the teacher, with more complex activities supported by video demonstrations and illustrations.

Within each kit, we provide grade-specific lists of all materials included, which you can also find using the links below.

Spanish-language support

Amplify Science Pennsylvania is committed to providing support to meet the needs of all learners, including multiple access points for Spanish-speaking students. Developed in conjunction with Spanish-language experts and classroom teachers, several components are available in Spanish across the Amplify Science Pennsylvania curriculum.

Spanish-language materials include:

COMPONENT TEACHER/STUDENT
Student Investigation Notebooks Student
Science articles Student
Video transcripts Student
Digital simulation translation keys Student
Printed classroom materials
Unit and chapter questions, key concepts, vocabulary cards, etc.		 Teacher
Copymasters Teacher
Assessments Teacher
Digital student experience license
This license gives students access to the student resources in Spanish, including instructional text, articles, and assessments. Teachers can control student access to Spanish-language content through the digital Teacher’s Guide.		 Teacher
Spanish teacher support license
This license includes teacher talk, projections, downloadable PDFs of all print resources, and video transcripts and closed captioning in Spanish.		 Teacher

Resources to support your review

Contact us

Support is always available. Our team is dedicated to helping you every step of the way.

Contact your dedicated Pennsylvania representative here.

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

A man with curly brown hair and a beard, smiling broadly, wearing a suit, dress shirt, and floral tie, standing outdoors with trees and grass in the background.

Keenan Zambelli

Northeast & Central PA

Publisher presentation

The Lawrence Hall of Science

Developed by the science education experts at UC Berkeley’s Lawrence Hall of Science and the digital learning team at Amplify, our program features:

  • phenomena-based approach where students construct a complex understanding of each unit’s anchor phenomenon.
  • A blend of cohesive storylines, hands-on investigations, rich discussions, literacy-rich activities, and digital tools.
  • Carefully crafted units, chapters, lessons, and activities designed to deliver true 3-dimensional learning.
  • An instructional design that supports all learners in accessing all standards.
Amplify Science and Lawrence Hall of Science

Instructional model

The Amplify Science program is rooted in the proven, research-based pedagogy of Do, Talk, Read, Write, Visualize. Here’s how each element works:

DO

First-hand investigations are an important part of any science classroom, and Amplify Science has students getting hands-on in every unit—from building models of protein molecules to experimenting with electrical systems.

TALK

Student-to-student discourse and full-class discussions are an integral part of the program. Students are provided with numerous opportunities to engage in meaningful oral scientific argumentation, all while fostering a collaborative classroom environment.

READ

Students read scientific articles, focusing their reading activities on searching for evidence related to their investigation and, importantly, on asking and recording questions as they read through fascinating texts on 21st-century topics.

WRITE

Following real-world practices, students write scientific arguments based on evidence they’ve collected, making clear their reasoning about how a given piece of evidence connects to one of several claims.

VISUALIZE

By manipulating digital simulations and using modeling tools to craft visualizations of their thinking— just as real scientists and engineers do—students take their learning far beyond the confines of what they can physically see in the classroom in an exciting and authentic way.

Program structure

Our cyclical lesson design ensures students receive multiple exposures to concepts through a variety of modalities. As they progress through the lessons within a unit, students build and deepen their understanding, increasing their ability to develop and refine complex explanations of the unit’s phenomenon.

It’s this proven program structure and lesson design that enables Amplify Science to address 100% of the NGSS, and support students in mastering the Oregon Science Standards.

Graphic showing a research process with four steps: spark intrigue with a real-world problem, explore evidence, explain and elaborate, and evaluate claims, connected in a cycle with arrows.

Unit types

While every unit delivers three-dimensional learning experiences and engages students in gathering evidence from a rich collection of sources, each unit also serves a unique instructional purpose.

In grades 6–8:

  • One unit is a launch unit.
  • Three units are core units.
  • Two units are engineering internships.

Launch units are the first units taught in each year of Amplify Science. The goal of the Launch unit is to introduce students to norms, routines, and practices that will be built on throughout the year, including argumentation, active reading, and using the program’s technology. For example, rather than taking the time to explain the process of active reading in every unit in a given year, it is explained thoroughly in the Launch unit, thereby preparing students to read actively in all subsequent units.

Core units establish the context of the unit by introducing students to a real-world problem. As students move through lessons in a Core unit, they figure out the unit’s anchoring phenomenon, gain an understanding of the unit’s disciplinary core ideas and science and engineering practices, and make linkages across topics through the crosscutting concepts. Each Core unit culminates with a Science Seminar and final writing activity.

Engineering Internship units invite students to design solutions for real-world problems as interns for a fictional company called Futura. Students figure out how to help those in need, from tsunami victims in Sri Lanka to premature babies, through the application of engineering practices. In the process, they apply and deepen their learning from Core units.

Unit sequence

Our lessons follow a structure that is grounded in regular routines while still being flexible enough to allow for a variety of learning experiences.

In fact, our multi-modal instruction offers more opportunities for students to construct meaning, and practice and apply concepts than any other program. What’s more, our modular design means our units can be flexibly arranged to support your instructional goals.

Three columns listing education curriculum topics for grades 6, 7, and 8, focusing on science themes such as microbiomes, mars geology, and harnessing human energy.

Program components

Available digitally and in print, our unit-specific reference guides are chock full of helpful resources, including scientific background knowledge, planning information and resources, color-coded 3-D Statements, detailed lesson plans, tips for delivering instruction, and differentiation strategies.

Amplify Science TG

Hands-on learning is an essential part of Amplify Science, and is integrated into every unit. Students actively participate in science, playing the roles of scientists and engineers as they gather evidence, think critically, solve problems, and develop and defend claims about the world around them. Every unit includes hands-on investigations that are critical to achieving the unit’s learning goals.

A young person wearing gloves looks through a microscope at a table with laboratory supplies, including bottles, slides, and a tray, against a plain blue background.

More hands-on with Flextensions:
Hands-on Flextensions are additional, optional investigations that are included at logical points in the learning progression and give students an opportunity to dig deeper if time permits. These activities offer teachers flexibility to choose to dedicate more time to hands-on learning. Materials referenced in Hands-on Flextension activities will either be included in the unit kit or are easily sourced. Supporting resources such as student worksheets will be included as downloadable PDF files.

Our kits include enough materials to support 200 student uses. In other words, teachers can easily support all five periods and small groups of 4-5 students each. Plus, our unit-specific kits mean teachers just grab the tub they need and then put it all back with ease.

Amplify Science California supports 3-D learning with more materials than any other program.

Our digital Simulations and Practice Tools are powerful resources for exploration, data collection, and student collaboration. They allow students the ability to explore scientific concepts that might otherwise be invisible or impossible to see with the naked eye.

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

In grades 6–8, one copy of the Student Investigation Notebook is included in each unit’s materials kit for use as a blackline master. Each notebook is also available as a downloadable PDF on the Unit Guide page of the digital Teacher’s Guide.

Two booklets titled "El clima cambiante de la Tierra: la desaparición del hielo" and "Earth’s Changing Climate: Vanishing Ice" with landscape illustrations on the covers.

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.

A laptop displays a PowerPoint presentation in presenter view, with slides about observing objects in plastic containers and related sensory instructions.

Full coverage of the Oregon Science Standards

Amplify Science was designed from the ground up to meet the Next Generation Science Standards (NGSS). As such, it aligns to the Oregon Science Standards, which were also borne out of the NGSS.

The guidance below is meant to provide support for integrating additional activities that support full coverage of Oregon’s standards. Organized by grade level, each section below will outline:

  • Additional activities that support 100% alignment to the Oregon Science Standards.
  • The standard being addressed with the activities.
  • The recommended placement of the activities within a specific Amplify Science unit.
  • PDFs of any accompanying materials that are necessary to implement the activities.

Activity Title: Meet a Scientist Who Changed How We Think About Brain Cells

About this activity: In this activity, students read a short article about a scientist who studied the nervous system.

Recommended placement: Metabolism unit, Lesson 3.2

Materials:

Instructions: Download the PDF “Meet a Scientist Who Changed How We Think About Brain Cells” above and remind students of the Active Reading guidelines. Before students read the article, invite them to share prior experiences. Then have students complete the copymaster above.

Activity Title: Meet a Scientist Who Studies Underwater Currents

About this activity: In this activity, students read a short article about a scientist who studies ocean currents.

Recommended placement: Oceans, Atmosphere, and Climate unit, Lesson 2.1

Materials:

Instructions: Download the PDF “Meet a Scientist Who Studies Underwater Currents” above and remind students of the Active Reading guidelines. Before students read the article, invite them to share prior experiences. Then have students complete the copymaster above.

Activity Title: Meet a Scientist Who Studies How the Environment Affects Our Traits

About this activity: In this activity, students read two short articles, one about current research on genes and proteins, and one about a scientist who is studying how the environment can affect our traits.

Recommended placement: Traits and Reproduction unit, Lesson 2.4

Materials:

Instructions: Download the PDF “Meet a Scientist Who Studies How the Environment Affects Our Traits” above and remind students of the Active Reading guidelines. Before students read the article, invite them to share prior experiences. Then have students complete the copymaster above.

Activity Title: Who Becomes a Space Scientist?

About this activity: In this activity, Students read a short article about a scientist who studies space.

Recommended placement: Geology on Mars unit, Lesson 3.1

Materials:

Instructions: Download the PDF “Who Becomes a Space Scientist?” above and remind students of the Active Reading guidelines. Before students read the article, invite them to share prior experiences. Then have students complete the copymaster above.

Activity Title: Meet a Scientist Who Studies How Plants Find Water Underground

About this activity: In this activity, students read a short article about a scientist who studies how plants’ roots get water.

Recommended placement: Matter and Energy in Ecosystems unit, Lesson 1.6

Materials:

Instructions: Download the PDF “Meet a Scientist Who Studies How Plants Find Water Underground” above and remind students of the Active Reading guidelines. Before students read the article, invite them to share prior experiences. Then have students complete the copymaster above.

Activity Title: Bringing Back the Buffalo

About this activity: In this activity, students change one competing population to try to decrease the other in the Sim, and read a short article about a scientist who studies buffalo.

Recommended placement: Populations and Resources unit, Lesson 3.2

Materials:

Instructions: Download the PDF “Bringing Back the Buffalo” above and remind students of the Active Reading guidelines. Before students read the article, invite them to share prior experiences. Then have students complete the copymaster above.

Activity Title: Rereading “A Continental Puzzle”

About this activity: In this activity, students reread “A Continental Puzzle” and think about how patterns were helpful to Wegener’s work.

Recommended placement: Plate Motion unit, Lesson 3.2

Materials:

Instructions: Direct students back to “A Continental Puzzle” above and remind students of the Active Reading guidelines. Before students re-read the article, invite them to share prior experiences. Then have students complete the copymaster above.

Activity Title: Meet a Scientist Who Studies Variation in Monkey Populations

About this activity: In this activity, students read a short article about a scientist who studies variation of traits in monkey populations.

Recommended placement: Natural Selection unit, Lesson 1.6

Materials:

Instructions: Download the PDF “Meet a Scientist Who Studies Variation in Monkey Populations” above and remind students of the Active Reading guidelines. Before students read the article, invite them to share prior experiences. Then have students complete the copymaster above.

Activity Title: Extinctions and Human Impacts

About this activity: The purpose of this lesson is for students to see how increases in human population and consumption of natural resources can negatively impact Earth’s systems.

Recommended placement: Natural Selection unit, Lesson 4.5

Materials:

Instructions: Download the PDF “Extinctions and Human Impacts” above and remind students of the Active Reading guidelines. Before students read the article, invite them to share prior experiences. Then have students complete the copymaster above.

Activity Title: Steno and the Shark

About this activity: In this activity, students read a short article about Nicolas Steno, a scientist from the 1600s whose studies of fossilized sharks’ teeth embedded in rock layers laid the foundation for the modern understanding of stratigraphy.

Recommended placement: Evolutionary History unit, Lesson 2.4

Materials:

Instructions: Download the PDF “Steno and the Shark” above and remind students of the Active Reading guidelines. Before students read the article, invite them to share prior experiences. Then have students complete the copymaster above.

Activity Title: Scale in the Solar System

About this activity: In this activity, students read and annotate the articles “Scale in the Solar System” and “The Solar System Is Huge.”

Recommended placement: Earth, Moon, and Sun unit, Lesson 1.2

Materials:

Instructions: Download the PDF “Scale in the Solar System” above and remind students of the Active Reading guidelines. Before students read the article, invite them to share prior experiences. Then have students complete the copymaster above.

Explore your print samples

Amplify Science physical samples can be found at the Hamersley Library at Western Oregon University. There you’ll find unit-specific Teacher’s References Guides and Student Investigation Notebooks for each grade level.

A note about the Teacher’s Reference Guides:

It’s important that your committee sees the full breadth and depth of our instruction. For that reason, we provided a copy of each of our unit-specific Teacher Reference Guides.

Rest assured that teachers do not use these robust reference guides for day-to-day teaching. For that, we have a hands-free TG!

A laptop screen shows an energy simulation, with surrounding text and diagrams explaining the Earth's system and energy flow.
  • Teacher Reference Guide: Unlike a typical TG that requires a series of supplemental books to support it, our encyclopedic reference guide is chock-full of everything a teacher needs to fully implement our program and the NGSS.
  • Ready-to-Teach Lesson Slides: For daily instruction, teachers need their hands free. That’s why we created ready-to-teach lesson slides for every single lesson What’s more, they are editable and include suggested teacher talk and point-of-use differentiation and other instructional tips. Click to learn more.

A note about the Materials Kits:

Hands-on learning is at the heart of Amplify Science, and is integrated into every unit. In order to make hands-on learning more manageable for busy teachers, Amplify Science materials are organized into unit-specific kits.

Stacked storage bins with labels, arranged neatly; caption notes they are a sample and may not reflect actual quantities or sizes.

Our unit-specific kits:

  • Include more materials — We give teachers enough materials to support 200 student uses.
  • Are more manageable — Unlike other programs that require large groups of students to share limited sets of materials, our kits include enough to support small groups of 4–5 students.
  • Include supportive videos — Each hands-on activity provides clear instructions for the teacher, with more complex activities supported by video demonstrations and illustrations.

At your request, we did not include our materials kits with our submissions samples. However, we did provide grade-specific lists of all materials included in each kit, which you can also find with the links below.

Access your digital samples

Explore as a teacher

Follow these instructions to explore the Amplify Science digital platform as a teacher.

  • Click the Access Amplify Science Platform button below.
  • Select Log in with Amplify.
  • Enter the teacher username and password found on your unique login flyer enclosed in your physical sample box.
  • Click the Science icon.
  • Click on the Grade Menu in the top center of the screen and select any grade.
  • Select any unit.
Access Amplify Science Platform

To help familiarize yourself with navigating the digital platform, watch the below navigational video.

Explore as a student

Follow these instructions to explore the Amplify Science digital platform as a student.

  • Click the Access Amplify Science Platform button below.
  • Select Log in with Amplify.
  • Enter the student username and password found on your unique login flyer enclosed in your physical sample box.
  • Click the Science icon.
  • Click on the Grade Menu in the top center of the screen and select any grade.
  • Select any unit.
Access Amplify Science Platform

Resources to support your review

Oregon standards correlation for grades 6–8

QCD Science Adoption Criteria 2022 for grades 6-8

QCD IMET Citation guidance for grades 6-8

Oregon Science IMET for grades 6-8 (Excel download)

Oregon QCD-IMET Citation guidance for grades 6-8

Research behind Amplify Science

Phenomena in grades 6–8

Program structure for grades 6–8

Active Reading in grades 6–8

Engineering in Amplify Science

Approaches to assessment in grades 6–8

Amplify Classroom and Polypad free and commercial use guidelines

If you’d like to use Amplify’s tools or content in your work, please review these guidelines to determine if your specific use is allowed and whether you need to submit a request for approval.

Overview

Amplify Classroom offers free prebuilt interactive and print-based lessons, interactive lesson-building tools, and Polypad virtual manipulatives. See amplify.com/classroom and polypad.amplify.com for more information.

Amplify Classroom features:

  • Activity Builder (labeled “Custom Activities” in the platform): This content-creating and publishing tool enables educators to create their own interactive lessons and edit existing lessons.
  • Polypad virtual manipulatives: These virtual manipulatives allow teachers and students to explore concepts, express their creativity, and visualize their thinking. Polypad virtual manipulatives can be embedded directly into lessons via Activity Builder or used as a stand-alone, dynamic workspace.
  • Computation Layer: This feature enables educators to further customize lessons created with Activity Builder. Computation Layer is the code that allows components within the lessons to “talk” to one another, enabling users to connect representations; customize content; and provide dynamic, interpretive feedback. Computation Layer is accessible through Activity Builder.

Amplify Classroom includes activities and lessons across many subjects, created by the thousands of educators on our platform. Content created by Amplify is tagged “By Amplify,” “By Amplify Classroom,” or “By Desmos Classroom.”

Amplify also publishes paid core curriculum programs, including Amplify Desmos MathAmplify ScienceAmplify CKLAAmplify Caminos, and Amplify ELA. These products can be reviewed and purchased by schools or districts interested in comprehensive resources aligned to standards and designed to motivate students. Some of the lessons that are free to use on Amplify Classroom (labeled Try It! lessons) are also part of these paid products. Learn more about our products and request a sample.

Amplify Classroom tools and content (other than paid products) are free for personal, educational, and non-commercial use, subject to our Acceptable Use Policy and Usage Guidelines. These guidelines also permit certain commercial uses. You generally don’t need to submit a request to use our free tools and resources for the permitted purposes covered in these guidelines. As long as you are following our Acceptable Use Policy and Usage Guidelines, as well as making appropriate Attributions and Disclaimers, you are permitted to move forward with your project. To make sure your use is permitted, please read these guidelines thoroughly and in their entirety. If you would like to explore a license for a use not permitted here, please submit this form.

Amplify does not own but partners with Desmos Studio, the maker of a suite of free math tools, including a graphing calculator used by over 75 million people around the world. (See desmos.com for more information.) Please contact Desmos Studio for information on using their content or tools.

Usage guidelines

Please adhere to the following guidelines for using Amplify Classroom tools and content in each of the scenarios set out below. You are required to follow our General Guidelines and Attribution requirements below when making permitted uses. You are responsible for clearing any third party marks and content you use in your applications or publications.

Uses labeled “PERMITTED USES” do not require permission, and you do not need to tell us about them—but we do appreciate hearing from you! Feel free to fill out this form to tell us about how you are using our tools and materials, and the ways in which you are finding them useful.

Uses labeled “CONTACT US” do require permission. If you are interested in such use, please submit this form, and someone from our team will endeavor to follow up with you as soon as possible.

Teaching and education services

This section provides guidelines on using Amplify Classroom for teaching and education services.

PERMITTED USES A green checkmark symbol on a light background. Educators creating, modifying (where permitted), and using Amplify Classroom content for classroom teaching in a school
  A green checkmark symbol on a light background. Public school districts, charter schools, and networks creating, modifying (where permitted) and using Amplify Classroom content for classroom teaching
  A green checkmark symbol on a light background. Private tutors creating or using Amplify Classroom content in 1:1 or small-group tutoring sessions
CONTACT US A large red "X" symbol on a light gray background. For-profit school or network of schools implementing Amplify Classroom for the school or network
  A large red "X" symbol on a light gray background. Education publishers and EdTech organizations (whether for profit or non-profit) using or linking to Amplify Classroom content and tools
  A large red "X" symbol on a light gray background. Any organizations or individuals embedding the teaching and learning experience from the Amplify Classroom lessons in their websites or applications (except API/iFrames Polypad integrations permitted below)
  A large red "X" symbol on a light gray background. Educators or other individuals authoring lessons for commercial purposes (e.g., to sell on Teachers Pay Teachers and similar websites)
  A large red "X" symbol on a light gray background. School districts, states, education publishers or technology providers, educators or any other individual or organization (whether for profit or non-profit) using Amplify Classroom content or platform to create paid curricula, educational courses, assessments, or any materials or curricula for submission for a state adoption list; or for offering, marketing, or sale to any schools or educational agencies or organizations, in or outside of the U.S.
  A large red "X" symbol on a light gray background. Instructional/tutoring organizations (whether for profit or non-profit), seeking to use Amplify Classroom for its tutors or instructors

Print and presentations

This section provides guidelines on including content from Amplify Classroom, such as portions of free lessons or images generated using our tools, in printed materials or presentations.

PERMITTED USES A green checkmark symbol on a light background. Books, including textbooks, up to two thousand copies
  A green checkmark symbol on a light background. Periodicals (newspapers, magazines, journals, etc.)
  A green checkmark symbol on a light background. Business documents such as company reports, proposals, presentations, etc.
  A green checkmark symbol on a light background. Academic publications, research papers, Ph.D. theses, and portfolios
  A green checkmark symbol on a light background. Conferences, presentations and accompanying slides
CONTACT US A large red "X" symbol on a light gray background. Books, more than two thousand copies, or as cover art for a book
  A large red "X" symbol on a light gray background. As content within platforms, mobile and tablet applications, PDFs, ebooks, multimedia materials, or other digital resources or products
  A large red "X" symbol on a light gray background. Consumer and retail goods or packaging (e.g., shirts, beach towels, shower curtains, mugs, posters, stationery)

Web and apps

This section provides guidelines for embedding Amplify Classroom tools into your platform.

PERMITTED USESA green checkmark symbol on a light background.Individuals and schools embedding Polypad in their materials for instructional use are permitted to do so; for integration options, see below.
 A green checkmark symbol on a light background.Organizations (whether for profit or non-profit) offering paid services embedding Polypad with <10k requests per year
CONTACT USA large red "X" symbol on a light gray background.Organizations (whether for profit or non-profit) offering paid services embedding Polypad with >10k requests per year
 A large red "X" symbol on a light gray background.Individuals or organizations looking to embed Activity Builder/Computation Layer in their applications
 A large red "X" symbol on a light gray background.Individuals or organizations looking to embed Amplify Classroom tools in larger applications, more complex integrations, white-labeling, or hosting Amplify’s JS files on their own infrastructure
 A large red "X" symbol on a light gray background.Polypad links, screenshots, iFrames, or API uses behind a paywall

Polypad integration options

There are two integration options for using Polypad within your own applications, including:

  • Using iFrames hosted by Amplify.
  • As a white-labeled JavaScript API that can be self-hosted and embedded in other websites or apps.

Developers can customize the features and behavior through numerous options and event listeners, and interact with the canvas programmatically to build custom functionality.

Visit the Polypad API page to learn more about Polypad API license terms and to generate API Key.

General guidelines

Copyright fair use

Your use of our content may be acceptable under principles of fair use (or other similar concepts in other countries). Under the fair use doctrine of the U.S. Copyright Act of 1976, it is permissible to use limited portions of a work for purposes such as commentary, criticism, news reporting, research, and scholarly reports.

Whether a particular use qualifies as fair use depends on a number of factors. For more information see resources from the U.S. Copyright Office, Circular 21Reproductions of Copyrighted Works by Educators and Librarians, and Fair Use Index. Amplify can’t tell you if your use of this content would be fair use, so you may wish to obtain your own legal advice.

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What is Amplify Science?

The Lawrence Hall of Science

Developed by the science education experts at UC Berkeley’s Lawrence Hall of Science and the digital learning team at Amplify, our program features:

  • phenomena-based approach where students construct a complex understanding of each unit’s anchor phenomenon.
  • A blend of cohesive storylines, hands-on investigations, rich discussions, literacy-rich activities, and digital tools.
  • Carefully crafted units, chapters, lessons, and activities designed to deliver true 3-dimensional learning.
  • An instructional design that supports all learners in accessing all standards.
Aerial view of the lawrence hall of science at the university of california, berkeley, showcasing the building and surrounding trees with a foggy city backdrop.

Proven to work

A pdf cover from wested titled "learning and literacy development together: initial results from a curriculum study," featuring an adult helping children with schoolwork in a classroom.

WestEd Randomized
Control Trial for Grade 1

Read More

Pdf cover titled "curriculum materials designed for the next generation science standards: initial results from gold standard research trials", published by wested.

WestEd Randomized
Control Trial for Grade 7

Read More

A teacher and students engage in a science activity around a table. The text promotes the Amplify Science K–8 curriculum, highlighting its focus on hands-on learning and real-world problem-solving.

Amplify Science NE
Grades K–5

Read More

Instructional model

The Amplify Science program is rooted in the proven, research-based pedagogy of Do, Talk, Read, Write, Visualize. Here’s how each element works:

Do

First-hand investigations are an important part of any science classroom, and Amplify Science has students getting hands-on in every unit—from building models of protein molecules to experimenting with electrical systems.

Talk

Student-to-student discourse and full-class discussions are an integral part of the program. Students are provided with numerous opportunities to engage in meaningful oral scientific argumentation, all while fostering a collaborative classroom environment.

Read

Students read scientific articles, focusing their reading activities on searching for evidence related to their investigation and, importantly, on asking and recording questions as they read through fascinating texts on 21st-century topics.

Write

Following real-world practices, students write scientific arguments based on evidence they’ve collected, making clear their reasoning about how a given piece of evidence connects to one of several claims.

Visualize

By manipulating digital simulations and using modeling tools to craft visualizations of their thinking— just as real scientists and engineers do—students take their learning far beyond the confines of what they can physically see in the classroom in an exciting and authentic way.

Program structure

Our cyclical lesson design ensures students receive multiple exposures to concepts through a variety of modalities. As they progress through the lessons within a unit, students build and deepen their understanding, increasing their ability to develop and refine complex explanations of the unit’s phenomenon.

It’s this proven program structure and lesson design that enables Amplify Science to address 100% of the NGSS, and support students in mastering the Utah Science Standards.

Flowchart depicting a critical thinking process with four circular nodes connected by arrows, each node representing a step: posing a real-world problem, exploring evidence, elaborating concepts, and evaluating claims.

Unit types

While every unit delivers three-dimensional learning experiences and engages students in gathering evidence from a rich collection of sources, each unit also serves a unique instructional purpose.

In grades 6–8:

  • One unit is a launch unit.
  • Three units are core units.
  • Two units are engineering internships.

Launch units are the first units taught in each year of Amplify Science. The goal of the Launch unit is to introduce students to norms, routines, and practices that will be built on throughout the year, including argumentation, active reading, and using the program’s technology. For example, rather than taking the time to explain the process of active reading in every unit in a given year, it is explained thoroughly in the Launch unit, thereby preparing students to read actively in all subsequent units.

Core units establish the context of the unit by introducing students to a real-world problem. As students move through lessons in a Core unit, they figure out the unit’s anchoring phenomenon, gain an understanding of the unit’s disciplinary core ideas and science and engineering practices, and make linkages across topics through the crosscutting concepts. Each Core unit culminates with a Science Seminar and final writing activity.

Engineering Internship units invite students to design solutions for real-world problems as interns for a fictional company called Futura. Students figure out how to help those in need, from tsunami victims in Sri Lanka to premature babies, through the application of engineering practices. In the process, they apply and deepen their learning from Core units.

Unit sequence

Our lessons follow a structure that is grounded in regular routines while still being flexible enough to allow for a variety of learning experiences.

In fact, our multi-modal instruction offers more opportunities for students to construct meaning, and practice and apply concepts than any other program. What’s more, our modular design means our units can be flexibly arranged to support your instructional goals.

Three columns listing education curriculum topics for grades 6, 7, and 8, focusing on science themes such as microbiomes, mars geology, and harnessing human energy.

Program components

Available digitally and in print, our unit-specific reference guides are chock full of helpful resources, including scientific background knowledge, planning information and resources, color-coded 3D Statements, detailed lesson plans, tips for delivering instruction, and differentiation strategies.

Amplify Science TG

Hands-on learning is an essential part of Amplify Science, and is integrated into every unit. Students actively participate in science, playing the roles of scientists and engineers as they gather evidence, think critically, solve problems, and develop and defend claims about the world around them. Every unit includes hands-on investigations that are critical to achieving the unit’s learning goals.

A young person wearing gloves looks through a microscope at a table with laboratory supplies, including bottles, slides, and a tray, against a plain blue background.

More hands-on with Flextensions:
Hands-on Flextensions are additional, optional investigations that are included at logical points in the learning progression and give students an opportunity to dig deeper if time permits. These activities offer teachers flexibility to choose to dedicate more time to hands-on learning. Materials referenced in Hands-on Flextension activities will either be included in the unit kit or are easily sourced. Supporting resources such as student worksheets will be included as downloadable PDF files.

Our kits include enough materials to support 200 student uses. In other words, teachers can easily support all five periods and small groups of 4-5 students each. Plus, our unit-specific kits mean teachers just grab the tub they need and then put it all back with ease.

Our digital Simulations and Practice Tools are powerful resources for exploration, data collection, and student collaboration. They allow students the ability to explore scientific concepts that might otherwise be invisible or impossible to see with the naked eye.

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

In grades 6–8, one copy of the Student Investigation Notebook is included in each unit’s materials kit for use as a blackline master. Each notebook is also available as a downloadable PDF on the Unit Guide page of the digital Teacher’s Guide.

Two booklets titled "El clima cambiante de la Tierra: la desaparición del hielo" and "Earth’s Changing Climate: Vanishing Ice" with landscape illustrations on the covers.

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.

A laptop displays a PowerPoint presentation in presenter view, with slides about observing objects in plastic containers and related sensory instructions.

Explore your print samples

With your Amplify Science print samples, you’ll find unit-specific Teacher’s References Guides and Student Investigation Notebooks for each grade level.

A note about the Teacher’s Reference Guides:

It’s important that your committee sees the full breadth and depth of our instruction. For that reason, we provided a copy of each of our unit-specific Teacher Reference Guides.

Rest assured that teachers do not use these robust reference guides for day-to-day teaching. For that, we have a hands-free TG!

Three laptop screens displaying educational content on earth's energy system, including diagrams and text annotations.
  • Teacher Reference Guide: Unlike a typical TG that requires a series of supplemental books to support it, our encyclopedic reference guide is chock-full of everything a teacher needs to fully implement our program and the NGSS.
  • Ready-to-Teach Lesson Slides: For daily instruction, teachers need their hands free. That’s why we created ready-to-teach lesson slides for every single lesson. What’s more, they are editable and include suggested teacher talk and point-of-use differentiation and other instructional tips. Click to learn more.

A note about the Materials Kits:

Hands-on learning is at the heart of Amplify Science, and is integrated into every unit. In order to make hands-on learning more manageable for busy teachers, Amplify Science materials are organized into unit-specific kits.

Stacked storage bins with labels, arranged neatly; caption notes they are a sample and may not reflect actual quantities or sizes.

Our unit-specific kits:

  • Include more materials — We give teachers enough materials to support 200 student uses.
  • Are more manageable — Unlike other programs that require large groups of students to share limited sets of materials, our kits include enough to support small groups of 4–5 students.
  • Include supportive videos — Each hands-on activity provides clear instructions for the teacher, with more complex activities supported by video demonstrations and illustrations.

At your request, we did not include our materials kits with our submissions samples. However, we did provide grade-specific lists of all materials included in each kit, which you can also find with the links below.

Access your digital samples

Explore as a teacher

Follow these instructions to explore the Amplify Science digital platform as a teacher.

  • Click the Access Amplify Science Platform button below and bookmark it.
  • Select Log in with Amplify.
  • Enter the username: t.msscienceut@tryamplify.net
  • Enter the password: AmplifyNumber1
  • Click the Science icon.
  • Click on the Grade Menu in the top center of the screen and select any grade.
  • Select any unit.
Access Amplify Science Platform

To help familiarize yourself with navigating the digital platform, watch the below navigational video.

Explore as a student

Follow these instructions to explore the Amplify Science digital platform as a student.

  • Click the Access Amplify Science Platform button below and bookmark it.
  • Select Log in with Amplify.
  • Enter the username: s.msscienceut@tryamplify.net
  • Enter the password: AmplifyNumber1
  • Click the Science icon.
  • Click on the Grade Menu in the top center of the screen and select any grade.
  • Select any unit.
Access Amplify Science Platform

Resources to support your review

Become an Amplify Tutor

Be the change in a student’s learning journey.

As an Amplify Tutor, you’ll facilitate a research-based curriculum for small groups of students to ensure they close academic gaps and build confidence.

A child wearing headphones raises their hand while attending an online class on a laptop, engaging with resources from the amplify curriculum.

What is Amplify Tutoring?

Amplify Tutoring is a full-service, high-impact virtual tutoring program that reaches students across the country. It ensures students receive high-quality live tutoring for a minimum of 30 minutes a day, 3 times per week.

A student wearing headphones attends a Virtual Tutoring Program for U.S. Tutors, watching a teacher point at a green bulletin board on a laptop screen.

Why be an Amplify Tutor?

As an Amplify Tutor, you will deliver our research-backed and evidenced-based intervention programs, virtually to a small group of students in 30 minute sessions, three times per week.

Flexibility: You will choose your desired number of hours and schedule that works best with your lifestyle.  Your schedule will then be matched with available tutoring groups within your selected regions.  

Support: Amplify will provide training to support your growth and impact.  Amplify tutors report a 40 percent increase in confidence after engaging in Amplify’s tutor training course.  You will also receive personalized coaching and support. 

Student Impact: Amplify Tutoring works for students who need it most: students who scored below benchmark, and participated regularly in Amplify Tutoring, made above-average growth. Tutored students were more likely to make outsized growth compared to peers with a similar risk profile who did not receive tutoring at their school.

Compensation: Amplify pays you for the time you spend planning for your groups as well as delivering tutoring to your groups. Amplify also provides paid initial training and ongoing professional development.

What Actual Tutors Have to Say

A woman sits at a desk in an office, smiling at a computer monitor with her laptop open, participating in a Virtual Tutoring Program for U.S. Tutors. Other people are visible working in the background.

Justine K

“And that’s a wrap on my first semester with Amplify! I find so much joy and fulfillment in working with these young learners. I am so proud of the growth each one has made. How I will miss these students but am so thankful for this company. The endless support, not only from leadership but from fellow tutors, is a rare find in today’s work culture. THANK YOU!”

Man wearing headphones sits at a desk, smiling and working on a laptop for a Virtual Tutoring Program for U.S. Tutors, with books and a pen holder nearby.

Adam S.

“As a tutor, I love Amplify’s science of reading approach to literacy. The reading rope incorporates language comprehension along with word recognition to develop skilled reading for students. Watching the science of reading improve students’ literacy skills has been one of the most rewarding experiences I have had in any career.”

A woman wearing headphones and a yellow hoodie sits at a desk with a notebook, pen, mug, and laptop, smiling as she participates in a Virtual Tutoring Program for U.S. Tutors during an online meeting or virtual class.

Britani H.

“Amplify Tutoring was a one of a kind experience as an educator where I was privileged to support students with their specific needs and goals. I always felt incredibly supported by all of the program managers and coaches because of their responsiveness and focused professional development throughout my journey as a tutor.”

Interested in tutoring math?

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We are thrilled to announce the continued expansion of our math tutoring program for students in grades 3 through 5! Introduced in the 2025–2026 school year, this program was designed to meet the growing need for personalized, high-quality math support during these critical foundational years.

Grounded in evidence-based practices, Amplify Desmos Math mini-lessons are aligned with the most critical topics at each grade level. Mini-lessons reinforce the same topics and content students see in core instruction to give students a double dosage. Students can be seen (and heard!) asking questions, debating answers, justifying their thinking, grappling with problems, and working together and independently.

As our program continues to grow, we are actively looking for passionate, dedicated tutors to join our team and make a lasting difference in young learners’ lives.Whether you have experience teaching multiplication, fractions, or general elementary math, we’d love to hear from you. Be part of something new, impactful, and expanding — apply to join our math tutoring team today!

S2-05: Moving students forward with project-based learning

A promotional image for the podcast "Science Connections" featuring guest Janis Lodge and the topic "Moving students forward with project-based learning." Season 2, Episode 5.

In this episode, Eric Cross sits with K–5 educator Janis Lodge to chat about building on her own science curriculum to create meaningful project-based learning experiences. Janis shares her work teaching Gifted and Talented Education (GATE), and how to use those practices to help accelerate the learning of all students. Eric and Janis also talk about making time for science within K–5 classrooms. Explore more from Science Connections by visiting our main page.

DOWNLOAD TRANSCRIPT

Janis Lodge (00:00):
To me, the reward of having those kids feel like they accomplished something and the way that they can take ownership of it and go in so many different directions, I cannot take that away from them. That’s such an opportunity that if I have the means to do it, I have to just take it and run with it.

Eric Cross (00:18):
Welcome to Science Connections. I’m your host, Eric Cross. My guest today is Janis Lodge. Janis is a third-grade teacher in Orange County, California, with a specialization in gifted and talented education. Recently, Janis was awarded the Orange County Council for the Gifted and Talented Education Classroom grant. This grant funds a project that provides an extension to her third-grade science unit about environments and survival. Through this project, students will think like a biomimicry engineer as they design a robot that is inspired by an innovation found in nature. In this episode, we discuss how she uses interdisciplinary teaching practices to make time for science learning; why gifted and talented education strategies can benefit all students; and her process for creating a problem-based lesson that ultimately earned her a grant for her classroom. And now, please enjoy my conversation with Janis Lodge. One, welcome! Thanks for being here.

Janis Lodge (01:14):
Of course, I am happy to do it. I’m excited for the opportunity.

Eric Cross (01:17):
Of course! Yeah. Elementary school teachers in science, I feel like there’s so many things to have conversations about. And some of the things that you’ve really focused on, I think, are, really, really important. But I wanna start off with your journey of you becoming a teacher in the classroom. And so, would you kind of give your background, your origin story? How did you end up as a third-grade teacher?

Janis Lodge (01:37):
Well, my story is definitely not a traditional story. Before I was a teacher, I was actually living in Maui, Hawaii. I moved there right after college. I went to Chico State in Northern California. And I got a degree in graphic design. And after I graduated, well, I should give a little bit of a backstory. My last summer before graduating, I spent the whole summer in Maui and I just fell in love with it. So when I graduated, I decided instead of applying for jobs in Northern California, I’m just gonna put some resumes out in Maui and see if I can get a job. And I did. I ended up getting a job doing graphic design and marketing for a kite surf company out there. And I ended up just staying for seven years on the island. And after about seven years, I kind of got a little bit of island fever and decided I wanted to come back to California. I wasn’t sure exactly what I wanted to do, but I just had this calling that I need to do something a little more fulfilling with my life. And I started thinking about different ideas and dreams I had. And I actually started thinking about when I was younger, right? I had this dream. If you were to ask me when I was 10 years old what I wanted to be when I grow up, it would be elementary school teacher.

Eric Cross (02:48):
Really?

Janis Lodge (02:48):
Believe it or not. When I was younger, I transformed my bedroom into a classroom. My stuffed animals were my students. I just thought I’m gonna be the next best teacher ever. And you know, as I went through life and kind of went in different directions, I kind of lost sight of that dream a little bit. But for some reason, when I decided to change careers, I just remembered that. And so I just decided to go get my teaching credential and see if it worked out. And it was probably the best decision I made. I feel like everything just fell perfectly into place. I ended up getting a job at an amazing school, and now, five years later, I’m a third grade teacher.

Eric Cross (03:28):
So one of the questions I have to ask, and talking to elementary school teachers, this comes up a lot: How do you make time for science as an elementary school teacher who’s teaching everything? And let me kind of premise this with, at least for those of us in California, and I’m sure the rest of the states too, but we know this; There’s kind of this pressure with pacing and then even, depending on what school you’re at, math and English tend to get the bulk of things. And maybe there’s this perception also of like, well, I gotta teach math and English, and sometimes science gets put to the back burner for different reasons.

Janis Lodge (03:57):
Well, you’re exactly right. The beginning of the year, we were provided with a pacing from the district. And you know, they try to keep us on track, saying, “You should be starting Unit 2 at this time.” But other than that, there’s really no specific guidelines of how many days we’re supposed to be teaching or for how long. But one kind of secret that I’ve discovered is that I can weave science into the other subjects, specifically with language arts. So quite often what I do is I take a look at the language arts standard, and if it’s identifying the key details and the main idea, well I can do that with the science books used from the curriculum. So I’ll just pull those readers and we’ll do the exact same skill, start with the same standard, but we’ll use the content from science. By doing that, we call that kind of like interdisciplinary study. And the students really enjoy that more, too, because they’re using the same skills but they’re diving deeper into the content.

Eric Cross (04:54):
Right.

Janis Lodge (04:55):
And so also that helps build the background knowledge. So then when it comes to time where, if I want to do a science lab or a science investigation, now they already have that background knowledge ’cause we already dove deep into the reading and they can apply that pretty quickly right away into their lab or whatever activity they’re doing.

Eric Cross (05:12):
Can you give an example maybe of how you might pull out something that might be a skill that you’re trying to develop, maybe in an English content, but you would pull that out in a science lesson, maybe? What would you do?

Janis Lodge (05:25):
We’re actually doing that right now. So we’re in our second unit of science and they’re studying inheritance and traits and they’re looking at different organisms to see how they have adaptations to help them survive in their environment. So coincidentally part of the literacy skills is to look at multiple sources, do research, and summarize and make analysis of what they’re reading. And so we have different varied resources. I have websites; I have books, ebooks, videos, and pictures. And they’re choosing which four sources they want to use. And then, then they’re coming up with a summary at the end and then putting together a Google Slides presentation based on whatever organism that they chose.

Eric Cross (06:05):
Did you have a science background before becoming an elementary school teacher?

Janis Lodge (06:11):
Um, none. Besides what I, you know, took in high school and college.

Eric Cross (06:16):
Did you find it easy to kind of lean into the science, or was it something you just kind of jumped into and said, “All right, I’m gonna get after it”?

Janis Lodge (06:23):
What’s interesting is if, you know, throughout my education, my favorite subjects were English and reading and writing and art. And quite honestly, science wasn’t my favorite subject. But I think because of that, that inspires me to come up with creative ways of presenting the information to them and making it exciting and engaging for them, because I don’t want them to feel that way. I want them to be excited about all subjects. And I think that’s the beauty of combining the different subjects like I mentioned before. Like I say, you know, “What would a scholar do? Think like a wildlife biologist. And like with my project, think like a biomimicry engineer.” And so it kind of shifts their thinking. Like, it’s not just, “Oh, we have to study science.” It’s like, “No, you are the scientist; you are a meteorologist; or you are an author. How would an author write about this? How would an illustrator capture this in a photo or a comic strip?” And so, when you really combine those disciplines, you can take it to another level. So even if science isn’t their favorite subject, like maybe it wasn’t for me growing up, they can still take something they’re passionate about and apply the science content to it and they really resonate with them.

Eric Cross (07:37):
You leaned into your strengths. Which are more like, coming into it, you had all these kind of creative strengths. You have that background as a graphics designer. You were into the arts. But then with those strengths, did that kinda give you more confidence to dive into the science work, because you approached it from your assets that you were already coming to the table with?

Janis Lodge (07:55):
Yeah.You said it perfectly. If you look at it from a different lens, there’s all these different ways you can approach science.

Eric Cross (07:59):
I find it in my own science class, too. We’re all teaching the same standards. But how I approach it is through Eric Cross’s kind of personality and understanding and my angle, and another teacher might do it a different way. But we’re all leading to the same destination.

Janis Lodge (08:14):
Exactly.

Eric Cross (08:15):
That kind of leads me to my next question, and this is having to do with the project that you just alluded to. The biomimicry project. So you did a biomimicry project. Would you consider that like a project based-learning assignment?

Janis Lodge (08:26):
Well, this will be the third year that I’ve taught this unit. And when I wrapped it up last year, it’s through the Amplify Science program, and they do a wonderful job of having a lot of investigations and really thinking like a biomimicry engineer. But the final part of the unit was to design a robot inspired by a giraffe, to eliminate invasive plants in a particular environment. And the project part of it at the end was to create a model using Popsicle sticks and pipe cleaners. And then the other part of it was a digital simulation where they would put in different shape structures of teeth, and kind of reconfigure the shape of the mouth. And then they’d put in what they think is effective, and then the computer would say, oh, you’re 98% successful or 70% successful. And I remember at the end of it the students were like, “OK, well when do we make the robots?” And I thought, “Well, we’re just doing the simulation, or we’re just doing this model out of Popsicle sticks; we’re not actually gonna make a robot.” And they just seemed so disappointed. And that’s kind of how the wheels started turning my head like, “Well, what if they actually could make a robot? The only thing stopping me is I don’t have the materials to do it.” So, shortly after that unit wrapped up, coincidentally I saw the email about this grant opportunity that was being offered through the Orange County Council for Gifted Education. And they said, If you have a project that you wanna get funded that would promote GATE strategies within the classroom, then you can submit this proposal. So that’s how the ball got rolling for that proposal. And I researched different robotics kits and different companies and I found one that was really user-friendly for third graders, and not so difficult for me to learn as well.

Eric Cross (10:10):
You’re a risk taker. Like, I’m already seeing this as I’m talking to you. Is that just who you are or do you have a network? Like what keeps you taking these risks?

Janis Lodge (10:18):
I don’t really consider it a risk, because it’s exciting for me. Like I said, I don’t know that much about robotics, but the idea of learning more and then teaching that to my students is exciting. And you know, there was a little bit of risk ’cause I’m deviating a little bit from the curriculum, from the standard lesson, but to me, the reward of having those kids feel like they accomplished something, and the way that they can take ownership of it and go in so many different directions, and on top of that, develop coding skills and computer science skills and robotic skills, to me it was just like I cannot take that away from them. That’s such an opportunity that if I have the means to do it, I have to just take it and run with it. So I think just being inspired by the potential outcomes of what could happen is what made me take that risk.

Eric Cross (11:05):
Did you just kind of create this from scratch? Did you work with a team of people? How did you come to the point where you were ready to present this for the grant?

Janis Lodge (11:12):
Pretty much from scratch. Like I said, the Amplify unit, it does teach them about robotics that were inspired by nature. So some of the materials that they read, and there’s some videos that show really great examples. There’s like a robotic arm that was inspired by an elephant trunk. There’s a book that shows what this field is, biomimicry engineer, they actually show like what they do in that field. And I thought this is a perfect way to apply it because the curriculum’s already pretty much set it up for me; now I just have to add this one final component to it. And essentially it becomes project-based learning at that point, because they’re taking their knowledge and their skills that they’ve learned up to that point. Even the unit that we’re doing doing right now is building up to it. So it’s kind of that final—instead of giving them a test at the end and saying, “OK, tell me what you learned about inheritance and traits and environments,” they can actually take that knowledge and apply it to an innovation or creation that comes out of their own mind, which is so much more powerful.

Eric Cross (12:11):
Do they connect to any other learning goals as they’re doing these projects?

Janis Lodge (12:15):
Well, I think first and foremost, the 21st century skills that from day one I tell them, the four Cs: collaboration, creativity, communication, and critical thinking. All of those are woven in through this lesson. From the beginning, we talked about the whole engineering design process. So from the beginning, they start with a question and oftentimes that actually can be the hardest for them to think about, “What’s a scientific question or a problem that I wanna solve?” If they’re passionate about, maybe, a sport or the environment or something within their school, I go, “There it is. OK, that’s the problem. How can you design something inspired by nature to solve that problem?” And then, from there they go into the planning and the designing and the testing and then the improving. So going through that engineering design process, I think, is what really makes them feel like they are the engineer going through this. And they can make mistakes. They can take risks. A lot of my students I’ve found are afraid to take risks. They wanna make sure they succeed. And they need that challenge to know that if they do fail, that’s OK. We can just revisit this. We can test it. We can look at it in a different way.

Eric Cross (13:27):
You maybe wonder about, how do you assess something like this?

Janis Lodge (13:30):
I think that’s where all those stages along the way are important. Because I wanna make sure that they have a plan and that it’s based on the knowledge that they’ve gained in the unit. I think one of the other things about project-based learning is the final product of how they demonstrate their mastery. And in my classroom I oftentimes give them a choice of how they’re gonna present that to me. So maybe they’re going to write it out like an essay. Maybe they’re gonna create a Google slide. Maybe they’re gonna make a video. Maybe they’re going to—obviously in this part they will have the model, but they’ll have to have some way to explain it to me. And I think giving them that choice gives them the opportunity to show it in the way that’s meaningful to them.

Eric Cross (14:14):
And are you using like a rubric when you’re grading these assignments? Or, how do you actually grade it?

Janis Lodge (14:20):
Yes. So we have a rubric that’s provided to us for the written component that all the students will do at the end. But I can take that same rubric and see if they’ve applied that to the project. So even the verbiage wouldn’t really need to change. I think it’s still important that the students are able to demonstrate this in written form and so all of them will still complete that written component, but to also give them the opportunity to show that in the modality of their choice. I think is really important too.

Eric Cross (14:48):
Right. And you have some students that feel much more comfortable being able to present orally versus—

Janis Lodge (14:53):
Exactly.

Eric Cross (14:53):
—versus writing versus maybe doing a video. I mean, we see that in middle school and in high school too. Students show their knowledge or their understanding of a topic depending on the medium in different ways, and some better than others. Some may find that they can communicate it a lot better orally, but when pen goes to paper or fingers go to keyboard, you might grade it completely different, ’cause they’re not able to transfer what’s in their mind into writing. And the way you’re doing it, and giving that student choice, they probably have so much more buy-in, I’d imagine, because they get to pick what they get to do.

Janis Lodge (15:21):
Right.

Eric Cross (15:22):
You said something earlier and I wanna come back to it. So you mentioned GATE, and GATE is not something that I hear a lot in my world, but it was something I heard a lot when I was in school. There were kind of all of these perceptions and ideas about GATE. You’re a GATE teacher, correct?

Janis Lodge (15:38):
Right.

Eric Cross (15:39):
What is GATE, and what is it like being a GATE teacher? What are the misconceptions, if any, that you might have heard or come across?

Janis Lodge (15:46):
Well, so GATE stands for Gifted and Talented Education. And first and foremost, I think a misconception is that we’re just kind of doing whatever we want; we come up with our own lessons and teach a totally different curriculum. Which is definitely a myth. Because we start with the exact same standards as any other third grade class that you’d walk into. That’s definitely where we start. But I think in addition to the standards, we also implement what are called GATE standards: So they’re Depth, Complexity, Acceleration, and Novelty. And there’s a lot of tools that we use in the classroom, different strategies. You’ll see things like the prompts of Depth and Complexity. We’ll use things like “think like a disciplinarian”; I’m doing “think like a biomimicry engineer.” But really, all they are are just thinking tools and strategies to elevate students thinking and kind of go below that surface level of the content to dive deeper. It also provides opportunities for acceleration. So for example, our last science unit, it was on magnetic force, and there was a handful of students that just grasped the concepts right away, and they’re ready for something else. They’re ready for more rigor. They need some challenge. And so at that point I can kind of pull that group aside and provide some differentiation for them. And I said, “OK, well, you understand the concept of magnetic force, balanced forces. So now what I want you to do is think about something that you’re really passionate about, and how could you use magnetic force somewhere in that field—again to solve a problem, problem-based learning—and present it to me?” So they create this form, it’s like a “think like a disciplinarian” frame, and one of them was “think like a hockey player.” And he’s trying to think of a way that he can incorporate magnetic force. Anyway, I could go on and on. But basically it’s finding what these students’ passions are. And I do that with all my students. And I should probably preface this by saying that even though these are standards that I implement in my classroom because it’s a GATE classroom, these are practices and tools that can be applied to any learner, at any age. And they really just enrich the education for all students.

Eric Cross (18:02):
So your classroom is, is a mixed classroom. There’s GATE students and then general—

Janis Lodge (18:05):
Right.

Eric Cross (18:07):
—students, non-GATE students, in the same class. It’s interesting because I imagine GATE is kind of scaffolding up to a higher level, but then, you also said something that I’ve noticed when I’m creating scaffolds for my students to support them, who may not be at a grade level, maybe in reading or literacy or math, those same scaffolds can help all students.

Janis Lodge (18:27):
So yeah, I don’t just go, “OK, you’re my GATE students; I’m gonna use these practices on you.” I use it for the whole class. But I’m also surprised by having that mix of these different learning styles. A lot of times students are inspired by other students, or, you know, we have this big thing about one of the prompts is Multiple Perspectives. I try to do that as much as I can, because students are inspired by the ideas of their peers. And quite often, if they hear it from a peer, it could be exactly what I just said, but they heard their student say it in a different way and it just clicks and they’re like, “Wow, I get that.”

Eric Cross (19:00):
I think a lot of teachers struggle or, or maybe feel ill-equipped, to support higher-level students. Did you get trained to be a GATE teacher? First lemme ask that question: Did you get special training for this?

Janis Lodge (19:13):
Yes. I went through a course, I think it was like a six-week certification course, through my district.

Eric Cross (19:19):
OK, so you got a special training, which—I’ve been in the classroom for nine years; I teach at a university as an adjunct professor; but I’ve never been trained on teaching gifted or accelerated students. And I’m kind of wondering now, like, do you feel like it made you a better teacher?

Janis Lodge (19:33):
Absolutely.

Eric Cross (19:34):
And if so, how do I get to do this?

Janis Lodge (19:36):
Well, it’s through the county. I mean, anybody can get trained and certified how to teach this way. But, just like you said, I think coming out of that, my eyes were just open, and my biggest takeaway is that these practices, even though they are designed for gifted and talented, it really kind of reshaped my thinking about how I, number one, present material to the students, that I’m doing it in an engaging way, and I’m not just lecturing at them; there’s opportunities for them to collaborate and communicate and use multiple resources. So, you know, how I’m teaching has changed. And then also, how I’m providing opportunities for them to demonstrate their learning. And a lot of that is project-based learning, because once they have the knowledge and skills they need to do something with it. I mean, that’s really the true definition of innovation, is taking the skills or taking something that you’ve learned, and now go with it. Run with it.

Eric Cross (20:32):
How can we take what you’ve learned and then kind of spread it, so teachers have this in their toolkit, too? Like for me, I have multiple ways to be able to support reading and literacy and math and tools and sentence frames. And my students who have special learning plans, I have a have a lot of tool sets for that. I wanna build my tool sets for this other area for my students who want to continue, who wanna run, or go beyond, or even stretch themselves. I think we need to take some of the things that you’re doing and not make them kind of like this exclusive group, but also let’s share it with everyone, ’cause if everybody can access it—

Janis Lodge (21:03):
I agree.

Eric Cross (21:03):
—we might see a lot more potential or a lot more opportunities for students who might not otherwise have them.

Janis Lodge (21:08):
And one thing: My school, I’m really proud to say that my principal has seen that. You know, he’s like, “Well why are we just keeping this in the GATE classroom?” So he’s working on getting all of our teachers certified.

Eric Cross (21:19):
No, I love what you’re doing and your principal sounds, sounds awesome for doing that and recognizing that this can benefit more students than just the ones who, you know, pass the Raisin Test, I think it’s what it was called when I was taking it, or whatever it is back then.

Janis Lodge (21:31):
Exactly.

Eric Cross (21:32):
We’ve talked about project-based learning, the GATE classroom…I kind of wanna come back to you as we wrap up. Thinking about, like, the jobs that you and I do, and the people that listen to this podcast, we have one of the few jobs that people remember us for a lifetime. And I wanna ask you, who was someone that was maybe inspirational in your educational career, that inspired you, or is maybe one of the most memorable? You might have several…but who is someone that was memorable to you in your career, and why? Why were they memorable to you?

Janis Lodge (22:02):
Yeah. Well, obviously, when I was younger, I was definitely inspired by all my teachers. The fact that I turned my bedroom into a classroom…I just was just in awe of this profession. But I think one that really resonated with me was my junior year in high school. I was taking a newspaper class and the teacher was Mrs. Kavanaugh, and she really taught us everything from writing the articles to the editing, to putting the pages together. And I remember in that class I was working on this program called QuarkXPress. I don’t even know if it exists anymore. But I was just fascinated with putting all these pieces together that we’d worked on for so long and getting the articles, picking the pictures, the illustrations and the titles. And I remember her looking at me saying, “You really enjoy this, don’t you?” And I said, “Yeah.” And she said, “Well, I have a computer graphics elective class that you should take next year.” And I thought, “OK, I’d love to do this, this opportunity to expand my knowledge and my skills.” So because of that, I took the computer graphics class the next year and I just remember throughout the whole time, she was just constantly encouraging me and acknowledging my skills. And I find myself doing that as a teacher as well. ‘Cause that really resonated with me. And it’s funny, this summer I was going through some boxes of some old stuff from high school, and I found this handout that I had made, because I remember my senior year of high school, she said, “Janis, you know what? You’re doing such a great job; we have these new, incoming students coming into the newspaper class, and I’d love for you to actually teach them how to do this pagination on this QuarkXPress program. I want you to put something together and actually teach it to them.” I thought, “Wow, she believes in me that much that she’s gonna let me teach this to the incoming students.” But I think my takeaway from that was that she gave me the opportunity to take those skills and actually do something with them, to apply them right away.

Eric Cross (23:53):
Mrs. Kavanaugh. Miss Kavanaugh. Shout-out to Miss Kavanaugh. As you told that story, I heard you as a teacher because I’m hearing she’s applying these GATE strategies in that situation. That’s what that’s what I heard.

Janis Lodge (24:08):
Yeah, absolutely.

Eric Cross (24:09):
She personalized this learning. She created a specialized opportunity. You presented to a real audience that was authentic. It had this personalization in it and this rigor and this challenge and it made a huge impact. And it’s just amazing to listen to you and hear this come full-circle, and now you’re doing this with little ones. And I just wanna thank you for your time in doing the interview, sharing your story with how you became a teacher, your students, the projects that you do. And just like so many teachers, going the extra mile for your kids and bringing in these really important 21st century skills; they’re gonna be so much better off for it. And I know it makes my job easier when I get them in the classroom, so thank you.

Janis Lodge (24:49):
Yeah. Well, thank you for the opportunity.

Eric Cross (24:51):
My pleasure. Thanks so much for listening and we wanna hear more about you and the educators who inspire you. You can nominate them as a future guest on Science Connections by emailing STEM@amplify.com. That’s S -T-E-M at amplify dot com. And be sure to click subscribe, wherever you listen to podcasts, and join our Facebook group, Science Connections: The Community. Until next time.

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What Janis Lodge says about science

“The reward of having kids feel like they accomplished something and take ownership is such an opportunity [with project-based learning] that I have to run with it. Being inspired by the potential outcomes of what could happen is what made me take that risk.”

– Janice Lodge

3rd Grade Teacher, De Portola Elementary

Meet the guest

Janis Lodge is a third grade teacher in Orange County, California. Her career in education started six years ago when she decided to follow her passion of making a positive difference in the lives of young scholars. Prior to teaching, Janis lived in Maui, Hawaii for seven years, working in the field of graphic design, marketing, and hospitality. She has found that her interest in innovation, project-based learning, and inquiry-driven exploration has helped shape her into the educator she is today. STEAM is integrated regularly into her classroom, and her students continually develop 21st century skills through a variety of unique projects. ​​Janis is also a PAL (Peer Assistance Leadership) Advisor for her school, where she helps young leaders (4th-6th graders) cultivate their leadership skills and empowers them to make a positive difference in their school and community. Janis was recently awarded the Orange County Council for the Gifted & Talented Education Classroom Grant, which will provide an extension to the third grade Amplify Science Unit: Environments and Survival.

A woman with long blonde hair smiles at the camera; she is inside a circular frame with a small 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!

You might also like:

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Learn about how to build a collaborative, imaginative culture in the classroom t…

Three illustrated portraits of individuals in lab coats with scientific diagrams and abstract lines in the background, suggesting a focus on STEM fields.

Free posters

Inspire your K–8 students with two free bilingual posters of scientists.

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.

Bring joy into a STEM classroom

Check out an episode of the Math Teacher Lounge podcast about joyful math teachi…

Welcome to Physical Science

BACK TO MAIN 6–8 PAGE

Amplify Science California is so effective you can cover 100% of the NGSS in fewer lessons than other programs.
 
Plus, you can breathe a sigh of relief knowing we give you enough materials to support 200 students. In fact, our material kits:

  • Support small groups of 4-5 students.
  • Make organization and finding materials easy.
  • Last longer with only one of the nine kits requiring refills.
A collage of four images: a magnet illustration, hands with a compass and balls, hands holding a bar magnet and ruler, and a graphic of Earth with compass needles.

What students learn

Lauren Learner loves science. Watch this video to find out what she learns in second 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.
An illustration from the Harnessing Human Energy unit

Unit 1

Harnessing Human Energy

Student role: Energy scientists

Phenomenon: Rescue workers can use their own human kinetic energy to power electrical devices used during rescue missions.

An illustration from the Force and Motion unit

Unit 2

Force and Motion

Student role: Physicists

Phenomenon: The asteroid sample-collecting pod collided with the docking station and failed to dock as planned.

See how this unit works

An illustration from the Force and Motion: Engineering Internship unit

Unit 3

Force and Motion Engineering Internship

Student role: Mechanical engineering interns

Phenomenon: Designing emergency supply delivery pods with different structures can better protect pods and their contents.

An illustration from the Magnetic Fields unit

Unit 4

Magnetic Fields

Student role: Physicists

Phenomenon: During its third magnetic spacecraft launcher test, a model spacecraft far exceeded its target speed.

An illustration from the Thermal Energy unit

Unit 5

Thermal Energy

Student role: Thermal scientists

Phenomenon: Riverdale School needs a new heating system. Only one of two proposed systems is the best choice.

See how this unit works

An illustration from the Phase Change unit

Unit 6

Phase Change

Student role: Chemists

Phenomenon: A methane lake on Titan no longer appears in images taken by a space probe two years apart.

See how this unit works

An illustration from the Phase Change: Engineering Internship unit

Unit 7

Phase Change Engineering Internship

Student role: Chemical engineering interns

Phenomenon: Designing portable baby incubators with different phase change materials helps keep babies’ temperatures healthy.

An illustration from the Chemical Reactions unit

Unit 8

Chemical Reactions

Student role: Forensic chemists

Phenomenon: A mysterious reddish-brown substance has been detected in the tap water of Westfield.

See how this unit works

An illustration from the Light Waves unit

Unit 9

Light Waves

Student role: Spectroscopists

Phenomenon: The rate of skin cancer in Australia is higher than other parts of the world despite getting the same or less sunlight.

See how this unit works

How teachers teach

Tom Teacher feels confident delivering 3-D instruction with our resources by his side. Watch this video to learn more. >

When you’re ready:

  • Scroll down and take a closer look at your classroom resources.
  • Click on the orange links below each component to see grade-specific samples.
Most adopted curriculum for the NGSS California

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.

Video introduction to Classroom Slides

An educational website open on a laptop displaying a lesson about force and motion: docking failure in space alongside a teacher guide notebook.

Teacher’s Reference Guide

Available digitally and in print, our unit-specific reference guides are chock full of helpful resources, including scientific background knowledge, planning information and resources, color-coded 3-D Statements, detailed lesson plans, tips for delivering instruction, and differentiation strategies.

Login to platform below to access

Amplify Science California supports 3-D learning with more materials than any other program.

Materials Kits

Our kits include enough non-consumable materials to support 200 student uses. In other words, you have enough materials to support all five periods and small groups of 4-5 students each. Plus, our unit-specific kits mean you just grab the tub you need and then put it all back with ease.

A digital simulation from Amplify Science

Simulations and Practice Tools

Our digital Simulations and Practice Tools are powerful resources for exploration, data collection, and student collaboration. They allow students the ability to explore scientific concepts that might otherwise be invisible or impossible to see with the naked eye.

Video overview of digital tools

An open book with two pages displaying illustrations of a space docking failure incident, titled in both spanish and english.

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.

Sample Student Investigation Notebook

Sample Student Investigation Notebook (Spanish)

Cover of amplify science california student edition grade 8 integrated featuring illustrations of space, animals, and scientific diagrams.

Student Edition Hardcover

This durable Student Edition is grade-level specific and contains all of the articles that students refer to throughout the year. Districts may choose to pair these traditional student texts with our digital student experience or new 2-volume consumable notebook set.

Line drawing of a person using a laptop, with headphones and a line illustration of a rocket launching above their head, symbolizing creativity or inspiration in Boost Reading.


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

Navigating a Launch Unit

Launch units are the first units taught in each year of the program. The goal of a Launch unit is to introduce students to norms, routines, and practices that will be built on throughout the year.

Navigating an Engineering Internship

Engineering Internship units invite students to design solutions for real-world problems as interns for a fictional company called Futura. In the process, they apply and deepen their learning from Core units.

Navigating a Core Unit

Core units introduce a real-world problem and support students as they figure out the anchoring phenomenon and gain an understanding of the unit’s DCIs, SEPs, and CCCs.

Navigating Classwork and Reporting

Classwork is our new online grading tool that gives you quick and easy access to unreviewed work, student portfolios of work, and automatically generated differentiation groups.

Welcome to Life Science

BACK TO MAIN 6–8 PAGE

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

Plus, you can breathe a sigh of relief knowing we give you enough materials to support 200 students. In fact, our material kits:

  • Support small groups of 4-5 students.
  • Make organization and finding materials easy.
  • Last longer with only one of the nine kits requiring refills.
Collage of four images: underwater digital art, two students conducting a science experiment, hands constructing a structure from red straws, and an abstract painting of colorful figures.

What students learn

Lauren Learner loves science. Watch this video to find out what she learns in second 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.
An illustration from the Microbiome unit

Unit 1

Microbiome

Student role: Microbiological researchers

Phenomenon: The presence of 100 trillion microorganisms living on and in the human body keeps the body healthy.

An illustration from the Metabolism unit

Unit 2

Metabolism

Student role: Medical students

Phenomenon: Elisa, a teenager, is tired all the time. In fact, she can’t get through the day without feeling exhausted.

See how this unit works

An illustration from the Metabolism: Engineering Internship unit

Unit 3

Metabolism Engineering Internship

Student role: Food engineers

Phenomenon: Health bars with different molecular compositions meet the metabolic needs of patients or rescue workers.

An image from the Traits and Reproduction unit

Unit 4

Traits and Reproduction

Student role: Biomedical students

Phenomenon: Darwin’s bark spider offspring have different silk flexibility traits, even though they have the same parents.

An illustration of a whale with jellyfish and turtles from Amplify Science

Unit 5

Populations and Resources

Student role: Biologists

Phenomenon: The size of the moon jelly population in the fictional Glacier Sea has experienced a puzzling increase.

See how this unit works

An illustration from the Matter and Energy unit

Unit 6

Matter and Energy in Ecosystems

Student role: Ecologists

Phenomenon: A sealed biodome built by a group of Econauts mysteriously crashed despite following the advice of experts.

See how this unit works

Cartoon image of a yellow dinosaur among green dinosaurs, all with meat and vegetables on their backs, standing in a grassy landscape.

Unit 7

Natural Selection

Student role: Biologists

Phenomenon: The rough-skinned newt population in Oregon State Park has become more poisonous over time.

See how this unit works

An illustration from the Natural Selection: Engineering Internship unit

Unit 8

Natural Selection Engineering Internship

Student role: Clinical engineers

Phenomenon: Designing malaria treatment plans that use different combinations of drugs can reduce drug resistance development.

An illustration from the Evolutionary History unit

Unit 9

Evolutionary History

Student role: Paleontologists

Phenomenon: A mystery fossil at the Natural History Museum has similarities with both wolves and whales.

See how this unit works

How teachers teach

Tom Teacher feels confident delivering 3-D instruction with our resources by his side. Watch this video to learn more. >

When you’re ready:

  • Scroll down and take a closer look at your classroom resources.
  • Click on the orange links below each component to see grade-specific samples.
Most adopted curriculum for the NGSS California

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.

Video introduction to Classroom Slides

An open teacher's guide and a laptop displaying an educational website on metabolism, featuring colorful chapter thumbnails.

Teacher’s Reference Guide

Available digitally and in print, our unit-specific reference guides are chock full of helpful resources, including scientific background knowledge, planning information and resources, color-coded 3-D Statements, detailed lesson plans, tips for delivering instruction, and differentiation strategies.

Login to platform below to access

Assorted laboratory supplies including beakers, measuring cylinders, test tubes, pipettes, thermometers, and chemical reagents on a white background.

Materials Kits

Our kits include enough non-consumable materials to support 200 student uses. In other words, you have enough materials to support all five periods and small groups of 4-5 students each. Plus, our unit-specific kits mean you just grab the tub you need and then put it all back with ease.

A digital simulation from Amplify Science

Simulations and Practice Tools

Our digital Simulations and Practice Tools are powerful resources for exploration, data collection, and student collaboration. They allow students the ability to explore scientific concepts that might otherwise be invisible or impossible to see with the naked eye.

Video overview of digital tools

Two textbooks titled amplify science, one in spanish and english, featuring a spider on web the cover.

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.

Sample Student Investigation Notebook

Sample Student Investigation Notebook (Spanish)

Illustration for amplify science textbook cover, featuring a woman scientist with various science symbols like dna, parrot, rocket, and dinosaur on stylized background.

Student Edition Hardcover

This durable Student Edition is grade-level specific and contains all of the articles that students refer to throughout the year. Districts may choose to pair these traditional student texts with our digital student experience or new 2-volume consumable notebook set.

Line drawing of a person using a laptop, with headphones and a line illustration of a rocket launching above their head, symbolizing creativity or inspiration in Boost Reading.


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

Navigating a Launch Unit

Launch units are the first units taught in each year of the program. The goal of a Launch unit is to introduce students to norms, routines, and practices that will be built on throughout the year.

Navigating an Engineering Internship

Engineering Internship units invite students to design solutions for real-world problems as interns for a fictional company called Futura. In the process, they apply and deepen their learning from Core units.

Navigating a Core Unit

Core units introduce a real-world problem and support students as they figure out the anchoring phenomenon and gain an understanding of the unit’s DCIs, SEPs, and CCCs.

Navigating Classwork and Reporting

Classwork is our new online grading tool that gives you quick and easy access to unreviewed work, student portfolios of work, and automatically generated differentiation groups.

Welcome to Grade 8

BACK TO MAIN 6–8 PAGE

Amplify Science California is so effective you can cover 100% of the NGSS in fewer lessons than other programs.
 
Plus, you can breathe a sigh of relief knowing we give you enough materials to support 200 students. In fact, our material kits:

  • Support small groups of 4-5 students.
  • Make organization and finding materials easy.
  • Last longer with only one of the nine kits requiring refills.
Collage of four images: a spaceship in space, hands using a glue gun on crafts, a solar panel connected to bulbs, and an illustration of a person surfing with neon effects.

What students learn

Lauren Learner loves science. Watch this video to find out what she learns in eigth 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.
An illustration from the Harnessing Human Energy unit

Unit 1

Harnessing Human Energy

Student role: Energy scientists

Phenomenon: Rescue workers can use their own human kinetic energy to power electrical devices used during rescue missions.

An illustration from the Force and Motion unit

Unit 2

Force and Motion

Student role: Physicists

Phenomenon: The asteroid sample-collecting pod collided with the docking station and failed to dock as planned.

See how this unit works

An illustration from the Force and Motion: Engineering Internship unit

Unit 3

Force and Motion Engineering Internship

Student role: Mechanical engineering interns

Phenomenon: Designing emergency supply delivery pods with different structures can better protect pods and their contents.

An illustration from the Magnetic Fields unit

Unit 4

Magnetic Fields

Student role: Physicists

Phenomenon: During its third magnetic spacecraft launcher test, a model spacecraft far exceeded its target speed.

An illustration from the Light Waves unit

Unit 5

Light Waves

Student role: Spectroscopists

Phenomenon: The rate of skin cancer in Australia is higher than other parts of the world despite getting the same or less sunlight.

See how this unit works

An illustration from the Earth, Moon, and Sun unit

Unit 6

Earth, Moon, and Sun

Student role: Astronomers

Phenomenon: Pictures of specific features on the Moon can only be taken by an astrophotographer at certain times.

See how this unit works

Cartoon image of a yellow dinosaur among green dinosaurs, all with meat and vegetables on their backs, standing in a grassy landscape.

Unit 7

Natural Selection

Student role: Biologists

Phenomenon: The rough-skinned newt population in Oregon State Park has become more poisonous over time.

See how this unit works

An illustration from the Natural Selection: Engineering Internship unit

Unit 8

Natural Selection Engineering Internship

Student role: Clinical engineers

Phenomenon: Designing malaria treatment plans that use different combinations of drugs can reduce drug resistance development.

An illustration from the Evolutionary History unit

Unit 9

Evolutionary History

Student role: Paleontologists

Phenomenon: A mystery fossil at the Natural History Museum has similarities with both wolves and whales.

See how this unit works

How teachers teach

Tom Teacher feels confident delivering 3-D instruction with our resources by his side. Watch this video to learn more. >

When you’re ready:

  • Scroll down and take a closer look at your classroom resources.
  • Click on the orange links below each component to see grade-specific samples.
Most adopted curriculum for the NGSS California

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.

Video introduction to Classroom Slides

Sample Classroom Slides

An educational website open on a laptop displaying a lesson about “ force and motion: docking failure in space” alongside a teacher’s guide notebook.

Teacher’s Reference Guide

Available digitally and in print, our unit-specific reference guides are chock full of helpful resources, including scientific background knowledge, planning information and resources, color-coded 3-D Statements, detailed lesson plans, tips for delivering instruction, and differentiation strategies.

Login to platform below to access

Amplify Science California supports 3-D learning with more materials than any other program.

Materials Kits

Our kits include enough non-consumable materials to support 200 student uses. In other words, you have enough materials to support all five periods and small groups of 4-5 students each. Plus, our unit-specific kits mean you just grab the tub you need and then put it all back with ease.

List of investigations by unit

List of materials by unit

A digital simulation from Amplify Science

Simulations and Practice Tools

Our digital Simulations and Practice Tools are powerful resources for exploration, data collection, and student collaboration. They allow students the ability to explore scientific concepts that might otherwise be invisible or impossible to see with the naked eye.

Video overview of digital tools

List of digital tools by unit

Device calendars by unit

Open book displaying a bilingual spread about space docking failures, with illustrations of a spacecraft near the moon on a black background.

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.

Sample Student Investigation Notebook

Sample Student Investigation Notebook (Spanish)

Illustration on a textbook cover showing various science themes, including an astronaut, wildlife, and cells, titled

Student Edition Hardcover

This durable Student Edition is grade-level specific and contains all of the articles that students refer to throughout the year. Districts may choose to pair these traditional student texts with our digital student experience or new 2-volume consumable notebook set.

Line drawing of a person using a laptop, with headphones and a line illustration of a rocket launching above their head, symbolizing creativity or inspiration in Boost Reading.


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 the video to the right plus the ones below 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

Navigating a Launch Unit

Launch units are the first units taught in each year of the program. The goal of a Launch unit is to introduce students to norms, routines, and practices that will be built on throughout the year.

Navigating an Engineering Internship

Engineering Internship units invite students to design solutions for real-world problems as interns for a fictional company called Futura. In the process, they apply and deepen their learning from Core units.

Navigating a Core Unit

Core units introduce a real-world problem and support students as they figure out the anchoring phenomenon and gain an understanding of the unit’s DCIs, SEPs, and CCCs.

Navigating Classwork and Reporting

Classwork is our new online grading tool that gives you quick and easy access to unreviewed work, student portfolios of work, and automatically generated differentiation groups.

Welcome to Earth and Space Science

BACK TO MAIN 6–8 PAGE

Amplify Science California is so effective you can cover 100% of the NGSS in fewer lessons than other programs.
 
Plus, you can breathe a sigh of relief knowing we give you enough materials to support 200 students. In fact, our material kits:

  • Support small groups of 4-5 students.
  • Make organization and finding materials easy.
  • Last longer with only one of the nine kits requiring refills.
A collage of images: top left, digital art of a desert scene; top right, three kids doing a science experiment; bottom left, a hand holding a jar and two others beside; bottom right, digital art of a person and child in a field.

What students learn

Lauren Learner loves science. Watch this video to find out what she learns in sixth 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.
A barren, rocky desert landscape with rover tracks leading to a distant vehicle on a hill under a hazy sky.

Unit 1

Geology on Mars

Student role: Planetary geologists

Phenomenon: Analyzing data about landforms on Mars can provide evidence that Mars may have once been habitable.

Two prehistoric reptiles with long snouts and tails are near the shore, one on land and one in water, with plants, rocks, and an island in the background.

Unit 2

Plate Motion

Student role: Geologists

Phenomenon: Mesosaurus fossils have been found on continents separated by thousands of kilometers of ocean.

See how this unit works

Geometric design featuring a telescope, mountain, sound waves, and cosmic elements on a purple hexagonal background.

Unit 3

Plate Motion Engineering Internship

Student role: Mechanical engineering interns

Phenomenon: Patterns in earthquake data can be used to design an effective tsunami warning system.

Illustration of a cross-section of Earth showing a volcano near the ocean. Trees, mountains, and clouds are visible above, with subterranean layers below.

Unit 4

Rock Transformations

Student role: Geologists


Phenomenon: Rock samples from different U.S. regions look different, but have similar mineral compositions.

See how this unit works

A city skyline at night with a prominent full moon, stars in the sky, and a bridge silhouette on the left.

Unit 5

Earth, Moon, and Sun

Student role: Astronomers

Phenomenon: Pictures of specific features on the Moon can only be taken by an astrophotographer at certain times.

See how this unit works

Abstract artwork depicting a bright sun with blue and orange swirling patterns next to green hills under a sky with shades of blue, orange, and red.

Unit 6

Ocean, Atmosphere, and Climate

Student role: Climatologists

Phenomenon: During El Niño years, the air temperature in Christchurch, New Zealand is cooler than usual.

Ilustración de un pueblo con casas, campos y montañas bajo un cielo nublado con olas de viento o lluvia.

Unit 7

Weather Patterns

Student role: Forensic meteorologists

Phenomenon: The strong storms in Galetown didn’t just begin. They have become more and more severe over the years.

See how this unit works

Un oso polar se encuentra sobre un pequeño témpano de hielo en el océano con un sol naranja en el cielo y lejanas montañas heladas al fondo.

Unit 8

Earth’s Changing Climate

Student role: Climatologists

Phenomenon: The ice on Earth’s surface is melting.

See how this unit works

Abstract geometric design in shades of blue and purple featuring a hexagon with icons of a building, wrench, molecules, sun, paint can, and screwdriver.

Unit 9

Earth’s Changing Climate Engineering Internship

Student role: Civil engineers

Phenomenon: Designing rooftops with different modifications can reduce a city’s impact on climate change.

How teachers teach

Tom Teacher feels confident delivering 3-D instruction with our resources by his side. Watch this video to learn more. >

When you’re ready:

  • Scroll down and take a closer look at your classroom resources.
  • Click on the orange links below each component to see grade-specific samples.
A laptop displays a PowerPoint presentation in presenter view, with slides about observing objects in plastic containers and related sensory instructions.
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.

Video introduction to Classroom Slides

A printed teacher’s guide labeled “Plate Motion: Mystery of the Mesosaurus Fossils” is displayed next to a laptop showing the same curriculum’s digital interface.
Teacher’s Reference Guide

Available digitally and in print, our unit-specific reference guides are chock full of helpful resources, including scientific background knowledge, planning information and resources, color-coded 3-D Statements, detailed lesson plans, tips for delivering instruction, and differentiation strategies.

Login to platform below to access

Assorted rocks, plastic jars, stacks of clear plastic cups, wrapped candies, and scattered dice laid out on a white background.
Materials Kits

Our kits include enough non-consumable materials to support 200 student uses. In other words, you have enough materials to support all five periods and small groups of 4-5 students each. Plus, our unit-specific kits mean you just grab the tub you need and then put it all back with ease.

A laptop screen displaying a map with three ecosystem options, each illustrated by different animal icons and accompanied by relevant data lists.
Simulations and Practice Tools

Our digital Simulations and Practice Tools are powerful resources for exploration, data collection, and student collaboration. They allow students the ability to explore scientific concepts that might otherwise be invisible or impossible to see with the naked eye.

Video overview of digital tools

Two booklets titled "El clima cambiante de la Tierra: la desaparición del hielo" and "Earth’s Changing Climate: Vanishing Ice" with landscape illustrations on the covers.
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.

Cover of the "Amplify Science" Grade 8 textbook featuring illustrations of space, insects, technology, crowds, and scientific diagrams.
Student Edition Hardcover

This durable Student Edition is grade-level specific and contains all of the articles that students refer to throughout the year. Districts may choose to pair these traditional student texts with our digital student experience or new 2-volume consumable notebook set.

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

Navigating a Launch Unit

Launch units are the first units taught in each year of the program. The goal of a Launch unit is to introduce students to norms, routines, and practices that will be built on throughout the year.

Navigating an Engineering Internship

Engineering Internship units invite students to design solutions for real-world problems as interns for a fictional company called Futura. In the process, they apply and deepen their learning from Core units.

Navigating a Core Unit

Core units introduce a real-world problem and support students as they figure out the anchoring phenomenon and gain an understanding of the unit’s DCIs, SEPs, and CCCs.

Navigating Classwork and Reporting

Classwork is our new online grading tool that gives you quick and easy access to unreviewed work, student portfolios of work, and automatically generated differentiation groups.

A closer look at grades 6–8

Amplify Science is based on the latest research on teaching and learning and helps teachers deliver rigorous and riveting lessons through hands-on investigations, literacy-rich activities, and interactive digital tools that empower students to think, read, write, and argue like real scientists.

In the 6–8 classroom, this looks like students:

  • Collecting evidence from a variety of sources.
  • Making sense of evidence in a variety of ways.
  • Formulating convincing scientific arguments.

Is your school implementing the domain model? Click here.

Collage of four images showing children engaged in educational activities such as conducting experiments and crafting in a classroom setting.
A four-step process diagram: Spark intrigue, Explore evidence, Explain and elaborate, and Evaluate claims, connected by arrows, with an engagement statement below.

Program structure

Our cyclical lesson design ensures students receive multiple exposures to concepts through a variety of modalities. As they progress through the lessons within a unit, students build and deepen their understanding, increasing their ability to develop and refine complex explanations of the unit’s phenomenon.

It’s this proven program structure and lesson design that enables Amplify Science to teach less, but achieve more. Rather than asking teachers to wade through unnecessary content, we designed our 6–8 program to address 100% of the NGSS in fewer lessons than other programs.

Scope and sequence

Every year our grades 6–8 sequence consists of 9 units, with each unit containing 10–19 lessons. Lessons are written to last a minimum of 45-minutes, though teachers can expand or contract the timing to meet their needs.

A grid of educational icons, each representing a different science topic, such as earth and space science, life science, and physical science, with titles and lesson counts.

Unit types

Each unit delivers three-dimensional learning experiences and engages students in gathering evidence from a rich collection of sources, while also serving a unique purpose.

In grades 6–8, there are three types of units:

  • One unit is a launch unit.
  • Three units are core units.
  • Two units are engineering internships.
Launch units

Launch units are the first units taught in each year of Amplify Science. The goal of the Launch unit is to introduce students to norms, routines, and practices that will be built on throughout the year, including argumentation, active reading, and using the program’s technology. For example, rather than taking the time to explain the process of active reading in every unit in a given year, it is explained thoroughly in the Launch unit, thereby preparing students to read actively in all subsequent units.

Core units

Core units establish the context of the unit by introducing students to a real-world problem. As students move through lessons in a Core unit, they figure out the unit’s anchoring phenomenon, gain an understanding of the unit’s disciplinary core ideas and science and engineering practices, and make linkages across topics through the crosscutting concepts. Each Core unit culminates with a Science Seminar and final writing activity.

Engineering Internship units

Engineering Internship units invite students to design solutions for real-world problems as interns for a fictional company called Futura. Students figure out how to help those in need, from tsunami victims in Sri Lanka to premature babies, through the application of engineering practices. In the process, they apply and deepen their learning from Core units.

Units at a glance

Abstract digital artwork featuring a yellow human figure, red shapes, and a blue-toned screen, with vibrant, multicolored patterns and textures in the background.
Microbiome

Domain: Life Science

Unit type: Launch

Student role: Microbiological researchers

Phenomenon: The presence of 100 trillion microorganisms living on and in the human body may keep the body healthy.  

An abstract illustration of a person receiving an oral examination, with colorful geometric shapes and an eye chart in the background.
Metabolism

Domain: Life Science

Unit type: Core

Student role: Medical researchers

Phenomenon: Elisa, a young patient, feels tired all the time.  

Abstract orange background with geometric shapes, featuring icons of a vest, bar chart, leaf, beaker, fruit, medical stethoscope, and an envelope within a hexagonal frame.
Metabolism Engineering Internship

Domains: Life Science, Engineering Design

Unit type: Engineering internship

Student role: Food engineers

Phenomenon: Designing health bars with different molecular compositions can effectively meet the metabolic needs of patients or rescue workers.  

Six spiders with varying body colors (brown, yellow, blue, and red) and patterns are arranged on a dark, textured background, seemingly in a diagram or chart formation.
Traits and Reproduction

Domain: Life Science

Unit type: Core

Student role: Biomedical students

Phenomenon: Darwin’s bark spider offspring have different silk flexibility traits, even though they have the same parents.  

Illustration of a person with closed eyes in a red winter coat and hat, surrounded by falling snow and orange circles on a dark background.
Thermal Energy

Domain: Physical Science

Unit type: Core

Student role: Thermal scientists

Phenomenon: One of two proposed heating systems for Riverdale School will best heat the school. 

Abstract illustration of a sun with blue and orange rays over a colorful landscape featuring green hills and a vibrant sky.
Ocean, Atmosphere, and Climate

Domains: Earth and Space Science, Physical Science

Unit type: Core

Student role: Climatologists

Phenomenon: During El Niño years, the air temperature in Christchurch, New Zealand is cooler than usual.  

Illustration of clouds above a small town and farmland, with wind currents depicted swirling through the landscape under a blue sky.
Weather Patterns

Domains: Earth and Space Science, Physical Science

Unit type: Core

Student role: Forensic meteorologists

Phenomenon: In recent years, rainstorms in Galetown have been unusually severe.  

A polar bear stands on a small floating ice sheet in the ocean, surrounded by melting ice, with a red sun in the sky.
Earth’s Changing Climate

Domains: Earth and Space Science, Life Science

Unit type: Core

Student role: Climatologists

Phenomenon: The ice on Earth’s surface is melting.  

A purple hexagonal graphic with icons including a building, wrench, screwdriver, sun, molecules, paint bucket, and tiles on a geometric patterned background.
Earth’s Changing Climate Engineering Internship

Domains: Earth and Space Science, Engineering Design

Unit type: Engineering internship

Student role: Civil engineers

Phenomenon: Designing rooftops with different modifications can reduce a city’s impact on climate change.  

A robotic rover sits on a hill in a rocky, reddish landscape, with visible tracks in the dust leading to its current position under a hazy sky.
Geology on Mars

Domain: Earth and Space Science

Unit type: Launch

Student role: Planetary geologists

Phenomenon: Analyzing data about landforms on Mars can provide evidence that Mars may have once been habitable. 

Two green prehistoric reptiles with long snouts are near the shore; one is on land while the other swims in blue water, with plants, rocks, and an island in the background.
Plate Motion

Domain: Earth and Space Science

Unit type: Core

Student role: Geologists

Phenomenon: Mesosaurus fossils have been found on continents separated by thousands of kilometers of ocean, even though the Mesosaurus species once lived all together.  

A purple geometric background featuring a hexagonal badge with a telescope, mountain, audio wave, and star symbols inside.
Plate Motion Engineering Internship

Domains: Earth and Space Science, Engineering Design

Unit type: Engineering internship

Student role: Mechanical engineering interns

Phenomenon: Patterns in earthquake data can be used to design an effective tsunami warning system.  

Illustration showing an ocean, forest, and mountains with a smoking volcano, plus a cross-section of underground tectonic plates.
Rock Transformations

Domain: Earth and Space Science

Unit type: Core

Student role: Geologists

Phenomenon: Rock samples from the Great Plains and from the Rocky Mountains — regions hundreds of miles apart — look very different, but have surprisingly similar mineral compositions.  

Four stages of an orange popsicle melting on a stick, from fully frozen on the left to completely melted on the right, against a plain background.
Phase Change

Domains: Physical Science, Earth and Space Science

Unit type: Core

Student role: Chemists

Phenomenon: A methane lake on Titan no longer appears in images taken by a space probe two years apart

Green geometric background with an outlined hexagon containing icons: a parachute, ruler, letter "A," bandage, stacked blocks, and a folded corner paper.
Force and Motion Engineering Internship

Domains: Engineering Design, Physical Science

Unit type: Engineering internship

Student role: Chemical engineering interns

Phenomenon: Designing portable baby incubators with different combinations of phase change materials can keep babies at a healthy temperature. Domains: Engineering Design, Physical Science

Abstract illustration showing red and blue circles on a split blue and light background, representing molecular movement across a membrane or barrier.
Chemical Reactions

Domains: Physical Science, Life Science, Earth and Space Science

Unit type: Core

Student role: Forensic chemists

Phenomenon: A mysterious brown substance has been detected in the tap water of Westfield.  

An underwater scene with a large whale surrounded by turtles, jellyfish, and various fish swimming in different directions.
Populations and Resources

Domains: Life Science, Earth and Space Science

Unit type: Core

Student role: Biologists

Phenomenon: The size of the moon jelly population in Glacier Sea has increased. 

Low-poly digital illustration of a fox hunting a rabbit in a forest with pine trees, mushrooms, mountains, and the sun in the background. Another rabbit sits near the trees.
Matter and Energy in Ecosystems

Domains: Life Science, Earth and Space Science, Physical Science

Unit type: Core

Student role: Ecologists

Phenomenon: The biodome ecosystem has collapsed.  

Two people climb over rocks filled with electronic devices; inset illustrations show a boot, a belt of batteries, and a radio.
Harnessing Human Energy

Domains: Physical Science, Earth and Space Science, Engineering Design

Unit type: Launch

Student role: Energy scientists

Phenomenon: Rescue workers can use their own human kinetic energy to power the electrical devices they use during rescue missions.  

A spacecraft approaches and docks with a modular space station featuring large blue solar panels, set against a black space background.
Force and Motion

Domain: Physical Science

Unit type: Core

Student role: Physicists

Phenomenon: The asteroid sample-collecting pod failed to dock at the space station as planned.

Green graphic with hexagonal emblem showing an infant, a thermometer, layered materials, a medical symbol, and a flame icon.
Force and Motion Engineering Internship

Domains: Engineering Design, Physical Science

Unit type: Engineering internship

Student role: Chemical engineering interns

Phenomenon: Designing emergency supply delivery pods with different structures can maintain the integrity of the supply pods and their contents.

Illustration of a roller coaster car with passengers raising their arms as they descend a steep track against a blue sky with clouds.
Magnetic Fields

Domain: Physical Science

Unit type: Core

Student role: Physicists

Phenomenon: During a test launch, a spacecraft traveled much faster than expected.  

Illustration of the Earth with arrows representing radiation or energy entering the atmosphere from space, focused on the Asia-Pacific region.
Light Waves

Domains: Physical Science, Life Science, Earth and Space Science

Unit type: Core

Student role: Spectroscopists

Phenomenon: The rate of skin cancer is higher in Australia than in other parts of the world.

A city skyline at night with illuminated windows, a large full moon, stars in the sky, and a bridge visible on the left side.
Earth, Moon, and Sun

Domains: Earth and Space Science, Physical Science

Unit type: Core

Student role: Astronomers

Phenomenon: An astrophotographer can only take pictures of specific features on the Moon at certain times.  

Four polygonal dinosaurs walking in a row, three green and one yellow, each with a rock and purple spikes on their backs, set against a grassy background with a blue sky.
Natural Selection

Domains: Life Science, Earth and Space Science

Unit type: Core

Student role: Biologists

Phenomenon: The newt population in Oregon State Park has become more poisonous over time.  

Red geometric background featuring a hexagonal emblem with icons of a world map, mosquito, DNA strand, bar chart, and interconnected blocks.
Natural Selection Engineering Internship

Domains: Engineering Design, Life Science

Unit type: Engineering internship

Student role: Clinical engineers

Phenomenon: Designing malaria treatment plans that use different combinations of drugs can reduce drug resistance development while helping malaria patients.  

Two tortoises with long necks are by a river; one is browsing leaves from a bush while the other is walking near the water's edge.
Evolutionary History

Domains: Life Science, Earth and Space Science

Unit type: Core

Student role: Paleontologists

Phenomenon: A mystery fossil at the Natural History Museum has similarities with both wolves and whales.    

Resources

Pilot support brochure for 6–8 (Integrated)

Unit phenomena for 6–8

Take a closer look at the unit phenomena featured in each grade level.

Classroom Slides for 6–8

Your new hands-free TG is coming soon! These PowerPoints for every lesson make t…

What’s so phenomenal about phenomena?

Learn actionable strategies that will help you implement 3-D teaching and learni…

Active reading in 6–8

Scientists read and write with purpose too.

Investigations for 6–8

Explore the types of investigations that take place in middle school classrooms….

A laptop screen displaying a map with three ecosystem options, each illustrated by different animal icons and accompanied by relevant data lists.

Sims for 4–8

Approaches to assessment in 6–8

Learn about our middle school embedded assessments.

A closer look at grades 6–8

Amplify Science California is based on the latest research on teaching and learning and helps teachers deliver rigorous and riveting lessons through hands-on investigations, literacy-rich activities, and interactive digital tools that empower students to think, read, write, and argue like real scientists.

In the 6–8 classroom, this looks like students:

  • Collecting evidence from a variety of sources.
  • Making sense of evidence in a variety of ways.
  • Formulating convincing scientific arguments.

Is your school implementing the domain model? Click here.

Collage of four images showing children engaged in educational activities such as conducting experiments and crafting in a classroom setting.
A four-step process diagram with icons: spark a real-world problem, explore sources, explain and elaborate, and evaluate claims, all linking to engage with cohesive storylines.

Program structure

Our cyclical lesson design ensures students receive multiple exposures to concepts through a variety of modalities. As they progress through the lessons within a unit, students build and deepen their understanding, increasing their ability to develop and refine complex explanations of the unit’s phenomenon.

It’s this proven program structure and lesson design that enables Amplify Science California to teach less, but achieve more. Rather than asking teachers to wade through unnecessary content, we designed our 6–8 program to address 100% of the California NGSS in fewer lessons than other programs.

Scope and sequence

Every year our grades 6–8 sequence consists of 9 units, with each unit containing 10–19 lessons. Lessons are written to last a minimum of 45-minutes, though teachers can expand or contract the timing to meet their needs.

Chart displaying educational science topics for grades 6 to 8, categorized by grade level, duration in days, and number of classes. Includes subjects like microbiome, geology, and natural selection.

Unit types

Each unit delivers three-dimensional learning experiences and engages students in gathering evidence from a rich collection of sources, while also serving a unique purpose.

In grades 6–8, there are three types of units:

  • One unit is a launch unit.
  • Three units are core units.
  • Two units are engineering internships.
Launch units

Launch units are the first units taught in each year of Amplify Science California. The goal of the Launch unit is to introduce students to norms, routines, and practices that will be built on throughout the year, including argumentation, active reading, and using the program’s technology. For example, rather than taking the time to explain the process of active reading in every unit in a given year, it is explained thoroughly in the Launch unit, thereby preparing students to read actively in all subsequent units.

Core units

Core units establish the context of the unit by introducing students to a real-world problem. As students move through lessons in a Core unit, they figure out the unit’s anchoring phenomenon, gain an understanding of the unit’s disciplinary core ideas and science and engineering practices, and make linkages across topics through the crosscutting concepts. Each Core unit culminates with a Science Seminar and final writing activity.

Engineering Internship units

Engineering Internship units invite students to design solutions for real-world problems as interns for a fictional company called Futura. Students figure out how to help those in need, from tsunami victims in Sri Lanka to premature babies, through the application of engineering practices. In the process, they apply and deepen their learning from Core units.

Units at a glance

Abstract art with vibrant colors featuring a yellow silhouette of a person holding a book against a background of geometric shapes, swirling patterns, and bold textures.
Microbiome

Domain: Life Science

Unit type: Launch

Student role: Microbiological researchers

Phenomenon: The presence of 100 trillion microorganisms living on and in the human body may keep the body healthy.  

Abstract artwork of a person's side profile with geometric shapes and colorful patterns flowing from the head, holding a small sledgehammer. A vision chart is visible in the corner.
Metabolism

Domain: Life Science

Unit type: Core

Student role: Medical researchers

Phenomenon: Elisa, a young patient, feels tired all the time.  

Download unit guide

Orange abstract background with hexagonal shapes featuring icons of a bar chart, plant, safety vest, test tube, peach, and stethoscope.
Metabolism Engineering Internship

Domains: Life Science, Engineering Design

Unit type: Engineering internship

Student role: Food engineers

Phenomenon: Designing health bars with different molecular compositions can effectively meet the metabolic needs of patients or rescue workers.  

Imagen que muestra un gráfico de arañas de diferentes colores con patrones distintos de patas y cuerpo, incluidas variaciones de color marrón, amarillo y azul. El fondo es una superficie oscura y texturizada.
Traits and Reproduction

Domain: Life Science

Unit type: Core

Student role: Biomedical students

Phenomenon: Darwin’s bark spider offspring have different silk flexibility traits, even though they have the same parents.  

Download unit guide

Illustration of a person in a red hat and fur-lined coat with eyes closed, surrounded by large orange circles on a dark background.
Thermal Energy

Domain: Physical Science

Unit type: Core

Student role: Thermal scientists

Phenomenon: One of two proposed heating systems for Riverdale School will best heat the school. 

Download unit guide

Abstract artwork depicting a bright sun with blue and orange swirling patterns next to green hills under a sky with shades of blue, orange, and red.
Ocean, Atmosphere, and Climate

Domains: Earth and Space Science, Physical Science

Unit type: Core

Student role: Climatologists

Phenomenon: During El Niño years, the air temperature in Christchurch, New Zealand is cooler than usual.  

An illustration from the Weather Patterns unit
Weather Patterns

Domains: Earth and Space Science, Physical Science

Unit type: Core

Student role: Forensic meteorologists

Phenomenon: In recent years, rainstorms in Galetown have been unusually severe.  

Download unit guide

An illustration from the Earth's Changing Climate unit
Earth’s Changing Climate

Domains: Earth and Space Science, Life Science

Unit type: Core

Student role: Climatologists

Phenomenon: The ice on Earth’s surface is melting.  

Download unit guide

Abstract geometric design in shades of blue and purple featuring a hexagon with icons of a building, wrench, molecules, sun, paint can, and screwdriver.
Earth’s Changing Climate Engineering Internship

Domains: Earth and Space Science, Engineering Design

Unit type: Engineering internship

Student role: Civil engineers

Phenomenon: Designing rooftops with different modifications can reduce a city’s impact on climate change.  

A barren, rocky desert landscape with rover tracks leading to a distant vehicle on a hill under a hazy sky.
Geology on Mars

Domain: Earth and Space Science

Unit type: Launch

Student role: Planetary geologists

Phenomenon: Analyzing data about landforms on Mars can provide evidence that Mars may have once been habitable. 

Two prehistoric reptiles with long snouts and tails are near the shore, one on land and one in water, with plants, rocks, and an island in the background.
Plate Motion

Domain: Earth and Space Science

Unit type: Core

Student role: Geologists

Phenomenon: Mesosaurus fossils have been found on continents separated by thousands of kilometers of ocean, even though the Mesosaurus species once lived all together.  

Download unit guide

Geometric design featuring a telescope, mountain, sound waves, and cosmic elements on a purple hexagonal background.
Plate Motion Engineering Internship

Domains: Earth and Space Science, Engineering Design

Unit type: Engineering internship

Student role: Mechanical engineering interns

Phenomenon: Patterns in earthquake data can be used to design an effective tsunami warning system.  

Illustration of a cross-section of Earth showing a volcano near the ocean. Trees, mountains, and clouds are visible above, with subterranean layers below.
Rock Transformations

Domain: Earth and Space Science

Unit type: Core

Student role: Geologists

Phenomenon: Rock samples from the Great Plains and from the Rocky Mountains — regions hundreds of miles apart — look very different, but have surprisingly similar mineral compositions.  

Download unit guide

Ilustración que muestra las etapas de fusión de una paleta de naranja: entera, parcialmente derretida, más derretida y casi derretida por completo, con palitos de madera, sobre un fondo morado.
Phase Change

Domains: Physical Science, Earth and Space Science

Unit type: Core

Student role: Chemists

Phenomenon: A methane lake on Titan no longer appears in images taken by a space probe two years apart

Download unit guide

Green geometric background with a hexagonal emblem containing a parachute icon, ruler, bandage, and stacked layers on a gradient pattern.
Force and Motion Engineering Internship

Domains: Engineering Design, Physical Science

Unit type: Engineering internship

Student role: Mechanical engineering interns

Phenomenon: Designing emergency supply delivery pods with different structures can maintain the integrity of the supply pods and their contents.  

An illustration from the Chemical Reactions unit
Chemical Reactions

Domains: Physical Science, Life Science, Earth and Space Science

Unit type: Core

Student role: Forensic chemists

Phenomenon: A mysterious brown substance has been detected in the tap water of Westfield.  

Download unit guide

An illustration of a whale with jellyfish and turtles from Amplify Science
Populations and Resources

Domains: Life Science, Earth and Space Science

Unit type: Core

Student role: Biologists

Phenomenon: The size of the moon jelly population in Glacier Sea has increased. 

Download unit guide

Low-poly landscape with trees and mushrooms. A fox sniffs the ground, a rabbit sits nearby, and mountains and sun are in the background.
Matter and Energy in Ecosystems

Domains: Life Science, Earth and Space Science, Physical Science

Unit type: Core

Student role: Ecologists

Phenomenon: The biodome ecosystem has collapsed.  

Download unit guide

Two people climbing rocky terrain; illustrations show a hiking boot and a belt with gear.
Harnessing Human Energy

Domains: Physical Science, Earth and Space Science, Engineering Design

Unit type: Launch

Student role: Energy scientists

Phenomenon: Rescue workers can use their own human kinetic energy to power the electrical devices they use during rescue missions.  

Illustration of a futuristic space station with large solar panels, orbiting in deep space, emitting a blue glow from its propulsion system.
Force and Motion

Domain: Physical Science

Unit type: Core

Student role: Physicists

Phenomenon: The asteroid sample-collecting pod failed to dock at the space station as planned.

Download unit guide

Green geometric graphic featuring icons: a baby, thermometer, layers, medical alert, and a flame.
Phase Change Engineering Internship

Domains: Engineering Design, Physical Science

Unit type: Engineering internship

Student role: Chemical engineering interns

Phenomenon: Designing portable baby incubators with different combinations of phase change materials can keep babies at a healthy temperature.  

Illustration of a roller coaster filled with people, hands raised, going down a steep track against a bright blue sky with clouds.
Magnetic Fields

Domain: Physical Science

Unit type: Core

Student role: Physicists

Phenomenon: During a test launch, a spacecraft traveled much faster than expected.  

An illustration from the Light Waves unit
Light Waves

Domains: Physical Science, Life Science, Earth and Space Science

Unit type: Core

Student role: Spectroscopists

Phenomenon: The rate of skin cancer is higher in Australia than in other parts of the world.

Download unit guide

A city skyline at night with a prominent full moon, stars in the sky, and a bridge silhouette on the left.
Earth, Moon, and Sun

Domains: Earth and Space Science, Physical Science

Unit type: Core

Student role: Astronomers

Phenomenon: An astrophotographer can only take pictures of specific features on the Moon at certain times.  

Download unit guide

Four low-poly dinosaurs with missing body sections are standing in a row; one is yellow, and the others are green. They have purple spikes and red patches on their bodies.
Natural Selection

Domains: Life Science, Earth and Space Science

Unit type: Core

Student role: Biologists

Phenomenon: The newt population in Oregon State Park has become more poisonous over time.  

Download unit guide

Red geometric background with icons including a mosquito, DNA strand, bar chart, and world map inside a hexagon.
Natural Selection Engineering Internship

Domains: Engineering Design, Life Science

Unit type: Engineering internship

Student role: Clinical engineers

Phenomenon: Designing malaria treatment plans that use different combinations of drugs can reduce drug resistance development while helping malaria patients.  

Two giant tortoises with long necks stand near water; one tortoise feeds on leaves from a tree while the other is near dense vegetation.
Evolutionary History

Domains: Life Science, Earth and Space Science

Unit type: Core

Student role: Paleontologists

Phenomenon: A mystery fossil at the Natural History Museum has similarities with both wolves and whales.    

Download unit guide

Resources

Two middle school girls use a Student Investigation Notebook to take on the role of scientists and engineers

Pilot support brochure for 6–8 (Integrated)

See how we customized our instructional sequence to fully support the Utah SEEd…

An illustration of a whale with jellyfish and turtles from Amplify Science

Unit phenomena for 6–8

Take a closer look at the unit phenomena featured in each grade level.

A laptop screen displays a simulation about Earth's energy system, with surrounding images showing diagrams and energy flow models.

Classroom Slides for 6–8

Your new hands-free TG is coming soon! These PowerPoints for every lesson make t…

A child wearing safety goggles closely examines an object through a magnifying glass in a classroom setting.

What’s so phenomenal about phenomena?

Learn actionable strategies that will help you implement 3-D teaching and learni…

A student reviews a science textbook and looks at a laptop in a classroom, while other students work together on their science projects in the background.

Active reading in 6–8

Learn how we support students in learning how to interact with scientific texts….

A young person wearing gloves looks through a microscope at a table with laboratory supplies, including bottles, slides, and a tray, against a plain blue background.

Investigations for 6–8

Explore the types of investigations that take place in middle school classrooms….

A laptop screen displaying a map with three ecosystem options, each illustrated by different animal icons and accompanied by relevant data lists.

Sims for 4–8

Two students sit at desks writing in notebooks and using laptops in a classroom setting.

Approaches to assessment in 6–8

Learn about our middle school embedded assessments.

A science education kit includes goggles, measuring cups, books on ecosystems and fuel burning, seeds, a jar, game pieces, and soil. Authored by The Lawrence Hall of Science.

Program component list for 6–8 (Integrated)

Explore the components that come with each unit.

A closer look at grades 6–8 (domain)

Amplify Science is based on the latest research on teaching and learning and helps teachers deliver rigorous and riveting lessons through hands-on investigations, literacy-rich activities, and interactive digital tools that empower students to think, read, write, and argue like real scientists.

In the 6–8 classroom, this looks like students:

  • Collecting evidence from a variety of sources.
  • Making sense of evidence in a variety of ways.
  • Formulating convincing scientific arguments.

Is your school implementing the domain model? Click here.

Collage of four images showing children engaged in educational activities such as conducting experiments and crafting in a classroom setting.
A four-step process: Spark intrigue, Explore evidence, Explain and elaborate, and Evaluate claims, leading to ongoing engagement and building complexity.

Program structure

Our cyclical lesson design ensures students receive multiple exposures to concepts through a variety of modalities. As they progress through the lessons within a unit, students build and deepen their understanding, increasing their ability to develop and refine complex explanations of the unit’s phenomenon.

It’s this proven program structure and lesson design that enables Amplify Science to teach less, but achieve more. Rather than asking teachers to wade through unnecessary content, we designed our 6–8 program to address 100% of the NGSS in fewer lessons than other programs.

Scope and sequence

Every year our grades 6–8 sequence consists of 9 units, with each unit containing 10–19 lessons. Lessons are written to last a minimum of 45-minutes, though teachers can expand or contract the timing to meet their needs.

A grid of educational icons, each representing a different science topic, such as earth and space science, life science, and physical science, with titles and lesson counts.

Unit types

Each unit delivers three-dimensional learning experiences and engages students in gathering evidence from a rich collection of sources, while also serving a unique purpose.

In grades 6–8, there are three types of units:

  • One unit is a launch unit.
  • Three units are core units.
  • Two units are engineering internships.
Launch units

Launch units are the first units taught in each year of Amplify Science. The goal of the Launch unit is to introduce students to norms, routines, and practices that will be built on throughout the year, including argumentation, active reading, and using the program’s technology. For example, rather than taking the time to explain the process of active reading in every unit in a given year, it is explained thoroughly in the Launch unit, thereby preparing students to actively read in all subsequent units.

Core units

Core units establish the context of the unit by introducing students to a real-world problem. As students move through lessons in a Core unit, they figure out the unit’s anchoring phenomenon, gain an understanding of the unit’s disciplinary core ideas and science and engineering practices, and make linkages across topics through the crosscutting concepts. Each Core unit culminates with a Science Seminar and final writing activity.

Engineering Internship units

Engineering Internship units invite students to design solutions for real-world problems as interns for a fictional company called Futura. Students figure out how to help those in need, from tsunami victims in Sri Lanka to premature babies, through the application of engineering practices. In the process, they apply and deepen their learning from Core units.

Units at a glance

A rover sits on a rocky, reddish hill under a hazy sky, leaving visible tire tracks across the barren landscape.
Geology on Mars

Domain: Earth and Space Science

Unit type: Launch

Student role: Planetary geologists

Phenomenon: Analyzing data about landforms on Mars can provide evidence that Mars may have once been habitable.    

Two prehistoric marine reptiles with long snouts are near a rocky shoreline, one on land and one in the water, with an island and clouds in the background.
Plate Motion

Domain: Earth and Space Science

Unit type: Core

Student role: Geologists

Phenomenon: Mesosaurus fossils have been found on continents separated by thousands of kilometers of ocean, even though the Mesosaurus species once lived all together.    

A geometric badge with a mountain, telescope, and audio wave icons on a purple background with polygonal shapes.
Plate Motion Engineering Internship

Domain: Earth and Space Science

Unit type: Engineering internship

Student role: Mechanical engineering interns

Phenomenon: Patterns in earthquake data can be used to design an effective tsunami warning system.    

Illustration of a volcano by the sea with smoke, trees, mountains, and a cross-section showing a fault line beneath the ground.
Rock Transformations

Domain: Earth and Space Science

Unit type: Core

Student role: Geologists

Phenomenon: Rock samples from the Great Plains and from the Rocky Mountains — regions hundreds of miles apart — look very different, but have surprisingly similar mineral compositions.    

Illustration of a city skyline at night with buildings, a bridge, and a large full moon in a starry sky.
Earth, Sun, and Moon

Domain: Earth and Space Science

Unit type: Core

Student role: Astronomers

Phenomenon: An astrophotographer can only take pictures of specific features on the Moon at certain times.    

Abstract digital painting of a landscape with green hills, a red-orange horizon, and a large yellow sun surrounded by blue and orange swirling shapes on the right.
Ocean, Atmosphere, and Climate

Domain: Earth and Space Science

Unit type: Core

Student role: Climatologists

Phenomenon: During El Niño years, the air temperature in Christchurch, New Zealand is cooler than usual.    

Illustration of a town with houses and fields under a sky with large clouds and swirling wind patterns, set against a backdrop of hills and mountains.
Weather Patterns

Domain: Earth and Space Science

Unit type: Core

Student role: Forensic meteorologists

Phenomenon: In recent years, rainstorms in Galetown have been unusually severe.    

A polar bear stands on a small ice floe surrounded by water and floating ice under a red sun in an Arctic landscape.
Earth’s Changing Climate

Domain: Earth and Space Science

Unit type: Core

Student role: Climatologists

Phenomenon: The ice on Earth’s surface is melting.    

Hexagonal badge with icons including a wrench, building, sun, screwdriver, paint can, and molecules on a purple geometric background.
Earth’s Changing Climate Engineering Internship

Domain: Earth and Space Science

Unit type: Engineering internship

Student role: Civil engineers

Phenomenon: Designing rooftops with different modifications can reduce a city’s impact on climate change.    

Colorful abstract digital artwork featuring a yellow figure holding a device, with blue and red shapes and textured patterns in the background.
Microbiome

Domain: Life Science

Unit type: Launch

Student role: Microbiological researchers

Phenomenon: The presence of 100 trillion microorganisms living on and in the human body may keep the body healthy.    

An abstract illustration of a person having their mouth and throat examined with a tongue depressor, surrounded by colorful shapes, with an eye chart in the background.
Metabolism

Domain: Life Science

Unit type: Core

Student role: Medical researchers

Phenomenon: Elisa, a young patient, feels tired all the time.    

Geometric orange background with a hexagon icon displaying symbols for statistics, farming, healthcare, safety vest, chemistry, and agriculture.
Metabolism Engineering Internship

Domain: Life Science

Unit type: Engineering internship

Student role: Food engineers

Phenomenon: Designing health bars with different molecular compositions can effectively meet the metabolic needs of patients or rescue workers.    

Six spiders with different colors and stripe patterns are arranged in a grid pattern on a dark background, showing variations in leg and body color.
Traits and Reproduction

Domain: Life Science

Unit type: Core

Student role: Biomedical students

Phenomenon: Darwin’s bark spider offspring have different silk flexibility traits, even though they have the same parents.    

An underwater scene shows a whale surrounded by jellyfish, sea turtles, and fish, with sunlight filtering through the water.
Populations and Resources

Domain: Life Science

Unit type: Core

Student role: Biologists

Phenomenon: The size of the moon jelly population in Glacier Sea has increased.    

A low-poly landscape with trees, mushrooms, a rabbit sitting, and a fox bending down near another rabbit under a sunny sky with mountains in the background.
Matter and Energy in Ecosystems

Domain: Life Science

Unit type: Core

Student role: Ecologists

Phenomenon: What caused the mysterious crash of a biodome ecosystem?    

Three green dinosaurs and one yellow dinosaur stand in a row on grass, each with purple spikes and a red spot on their backs. The sky is blue with light clouds.
Natural Selection

Domain: Life Science

Unit type: Core

Student role: Biologists

Phenomenon: The newt population in Oregon State Park has become more poisonous over time.    

Red-toned graphic with hexagonal badge featuring a world map, a mosquito, a DNA strand, charts, cubes, and circular icons. Geometric background pattern.
Natural Selection Engineering Internship

Domain: Life Science

Unit type: Engineering internship

Student role: Clinical engineers

Phenomenon: Designing malaria treatment plans that use different combinations of drugs can reduce drug resistance development while helping malaria patients.  

Two giant tortoises are near a river; one is by the water and the other is standing on land and stretching its neck toward a leafy tree.

Evolutionary History

Domain: Life Science

Unit type: Core

Student role: Paleontologists

Phenomenon: A mystery fossil at the Natural History Museum has similarities with both wolves and whales.    

Two people climb over rocky terrain strewn with electronic waste, with illustrated insets showing a hiking boot, a solar-powered device, and a person adjusting a belt-like gadget.
Harnessing Human Energy

Domain: Physical Science

Unit type: Launch

Student role: Energy scientists

Phenomenon: Rescue workers can use their own human kinetic energy to power the electrical devices they use during rescue missions.    

A spacecraft approaches a modular space station with large solar panels, set against a backdrop of outer space.
Force and Motion

Domain: Physical Science

Unit type: Core

Student role: Physicists

Phenomenon: The asteroid sample-collecting pod failed to dock at the space station as planned.    

Green geometric background with a hexagonal badge showing a parachute, a box, a ruler, a bandage, and stacked layers.
Force and Motion Engineering Internship

Domain: Physical Science

Unit type: Engineering internship

Student role: Mechanical engineering interns

Phenomenon: Designing emergency supply delivery pods with different structures can maintain the integrity of the supply pods and their contents. 

Illustration of a roller coaster car full of people with raised arms, speeding down a loop against a blue sky with clouds.
Magnetic Fields

Domain: Physical Science

Unit type: Core

Student role: Physicists

Phenomenon: During a test launch, a spacecraft traveled much faster than expected.    

Illustration of a person in a red coat and hat with arms crossed, eyes closed, surrounded by large orange and brown circles, possibly representing snow or lights.
Thermal Energy

Domain: Physical Science

Unit type: Core

Student role: Thermal scientists

Phenomenon: One of two proposed heating systems for Riverdale School will best heat the school.    

An orange popsicle gradually melts, shown in four stages from solid to completely melted, with wooden sticks visible, against a purple background.
Phase Change

Domain: Physical Science

Unit type: Core

Student role: Chemists

Phenomenon: A methane lake on Titan no longer appears in images taken by a space probe two years apart.    

A green background with a picture of a person and a sandwich.
Phase Change Engineering Internship

Domain: Physical Science

Unit type: Engineering internship

Student role: Chemical engineering interns

Phenomenon: Designing portable baby incubators with different combinations of phase change materials can keep babies at a healthy temperature.    

Digital illustration showing red and blue molecules on a blue background transitioning to a lighter background, representing molecular diffusion across a boundary.
Chemical Reactions

Domain: Physical Science

Unit type: Core

Student role: Forensic chemists

Phenomenon: A mysterious brown substance has been detected in the tap water of Westfield.    

Illustration of Earth with yellow arrows and colored waves approaching from the left, representing incoming solar or cosmic radiation.
Light Waves

Domain: Physical Science

Unit type: Core

Student role: Spectroscopists

Phenomenon: The rate of skin cancer is higher in Australia than in other parts of the world.    

Resources

Pilot support brochure for grades 6–8 (Domain…

Unit phenomena for grade 6-8 (Domain)

Take a closer look at the unit phenomena featured in each grade level.

Classroom Slides for 6–8

Your new hands-free TG is coming soon! These PowerPoints for every lesson make t…

What’s so phenomenal about phenomena?

Learn actionable strategies that will help you implement 3-D teaching and learni…

Planning Guide for grades 6–8 (Domain)

Check out these tips for planning to teach.

Active reading in grades 6–8

Scientists read and write with purpose too.

Investigations for grades 6–8 (Domain)

Explore the types of investigations that take place in 6–8 classrooms.

A laptop screen displaying a map with three ecosystem options, each illustrated by different animal icons and accompanied by relevant data lists.

Sims for grades 4–8

Take a closer look at the digital simulations included at each grade level.

Approaches to assessment at 6–8

Learn about our embedded assessments.

A closer look at grades 6–8 (domain)

Amplify Science California is based on the latest research on teaching and learning and helps teachers deliver rigorous and riveting lessons through hands-on investigations, literacy-rich activities, and interactive digital tools that empower students to think, read, write, and argue like real scientists.

In the 6–8 classroom, this looks like students:

  • Collecting evidence from a variety of sources.
  • Making sense of evidence in a variety of ways.
  • Formulating convincing scientific arguments.

Is your school implementing the integrated model? Click here.

Collage of four images showing children engaged in educational activities such as conducting experiments and crafting in a classroom setting.
Graphic showing a research process with four steps: spark intrigue with a real-world problem, explore evidence, explain and elaborate, and evaluate claims, connected in a cycle with arrows.

Program structure

Our cyclical lesson design ensures students receive multiple exposures to concepts through a variety of modalities. As they progress through the lessons within a unit, students build and deepen their understanding, increasing their ability to develop and refine complex explanations of the unit’s phenomenon.

It’s this proven program structure and lesson design that enables Amplify Science California to teach less, but achieve more. Rather than asking teachers to wade through unnecessary content, we designed our 6–8 program to address 100% of the California NGSS in fewer lessons than other programs.

Scope and sequence

Every year of our grades 6–8 sequence consists of 9 units, with each unit containing 10–19 lessons. Lessons are written to last a minimum of 45 minutes, though teachers can expand or contract the timing to meet their needs.

A grid of educational icons, each representing a different science topic, such as earth and space science, life science, and physical science, with titles and lesson counts.

Unit types

Each unit delivers three-dimensional learning experiences and engages students in gathering evidence from a rich collection of sources, while also serving a unique purpose.

In grades 6–8, there are three types of units:

  • One unit is a launch unit.
  • Three units are core units.
  • Two units are engineering internships.
Launch units

Launch units are the first units taught in each year of Amplify Science California. The goal of the Launch unit is to introduce students to norms, routines, and practices that will be built on throughout the year, including argumentation, active reading, and using the program’s technology. For example, rather than taking the time to explain the process of active reading in every unit in a given year, it is explained thoroughly in the Launch unit, thereby preparing students to actively read in all subsequent units.

Core units

Core units establish the context of the unit by introducing students to a real-world problem. As students move through lessons in a Core unit, they figure out the unit’s anchoring phenomenon, gain an understanding of the unit’s disciplinary core ideas and science and engineering practices, and make linkages across topics through the crosscutting concepts. Each Core unit culminates with a Science Seminar and final writing activity.

Engineering Internship units

Engineering Internship units invite students to design solutions for real-world problems as interns for a fictional company called Futura. Students figure out how to help those in need, from tsunami victims in Sri Lanka to premature babies, through the application of engineering practices. In the process, they apply and deepen their learning from Core units.

Units at a glance

A barren, rocky desert landscape with rover tracks leading to a distant vehicle on a hill under a hazy sky.
Geology on Mars

Domain: Earth and Space Science

Unit type: Launch

Student role: Planetary geologists

Phenomenon: Analyzing data about landforms on Mars can provide evidence that Mars may have once been habitable.    

Two prehistoric reptiles with long snouts and tails are near the shore, one on land and one in water, with plants, rocks, and an island in the background.
Plate Motion

Domain: Earth and Space Science

Unit type: Core

Student role: Geologists

Phenomenon: Mesosaurus fossils have been found on continents separated by thousands of kilometers of ocean, even though the Mesosaurus species once lived all together.    

Download unit guide

Geometric design featuring a telescope, mountain, sound waves, and cosmic elements on a purple hexagonal background.
Plate Motion Engineering Internship

Domain: Earth and Space Science

Unit type: Engineering internship

Student role: Mechanical engineering interns

Phenomenon: Patterns in earthquake data can be used to design an effective tsunami warning system.    

Illustration of a cross-section of Earth showing a volcano near the ocean. Trees, mountains, and clouds are visible above, with subterranean layers below.
Rock Transformations

Domain: Earth and Space Science

Unit type: Core

Student role: Geologists

Phenomenon: Rock samples from the Great Plains and from the Rocky Mountains — regions hundreds of miles apart — look very different, but have surprisingly similar mineral compositions.    

Download unit guide

A city skyline at night with a prominent full moon, stars in the sky, and a bridge silhouette on the left.
Earth, Sun, and Moon

Domain: Earth and Space Science

Unit type: Core

Student role: Astronomers

Phenomenon: An astrophotographer can only take pictures of specific features on the Moon at certain times.    

Download unit guide

Abstract artwork depicting a bright sun with blue and orange swirling patterns next to green hills under a sky with shades of blue, orange, and red.
Ocean, Atmosphere, and Climate

Domain: Earth and Space Science

Unit type: Core

Student role: Climatologists

Phenomenon: During El Niño years, the air temperature in Christchurch, New Zealand is cooler than usual.    

Ilustración de un pueblo con casas, campos y montañas bajo un cielo nublado con olas de viento o lluvia.
Weather Patterns

Domain: Earth and Space Science

Unit type: Core

Student role: Forensic meteorologists

Phenomenon: In recent years, rainstorms in Galetown have been unusually severe.    

Download unit guide

Un oso polar se encuentra sobre un pequeño témpano de hielo en el océano con un sol naranja en el cielo y lejanas montañas heladas al fondo.
Earth’s Changing Climate

Domain: Earth and Space Science

Unit type: Core

Student role: Climatologists

Phenomenon: The ice on Earth’s surface is melting.    

Download unit guide

Abstract geometric design in shades of blue and purple featuring a hexagon with icons of a building, wrench, molecules, sun, paint can, and screwdriver.
Earth’s Changing Climate Engineering Internship

Domain: Earth and Space Science

Unit type: Engineering internship

Student role: Civil engineers

Phenomenon: Designing rooftops with different modifications can reduce a city’s impact on climate change.    

Abstract art with vibrant colors featuring a yellow silhouette of a person holding a book against a background of geometric shapes, swirling patterns, and bold textures.
Microbiome

Domain: Life Science

Unit type: Launch

Student role: Microbiological researchers

Phenomenon: The presence of 100 trillion microorganisms living on and in the human body may keep the body healthy.    

Abstract artwork of a person's side profile with geometric shapes and colorful patterns flowing from the head, holding a small sledgehammer. A vision chart is visible in the corner.
Metabolism

Domain: Life Science

Unit type: Core

Student role: Medical researchers

Phenomenon: Elisa, a young patient, feels tired all the time.    

Download unit guide

Orange abstract background with hexagonal shapes featuring icons of a bar chart, plant, safety vest, test tube, peach, and stethoscope.
Metabolism Engineering Internship

Domain: Life Science

Unit type: Engineering internship

Student role: Food engineers

Phenomenon: Designing health bars with different molecular compositions can effectively meet the metabolic needs of patients or rescue workers.    

Imagen que muestra un gráfico de arañas de diferentes colores con patrones distintos de patas y cuerpo, incluidas variaciones de color marrón, amarillo y azul. El fondo es una superficie oscura y texturizada.
Traits and Reproduction

Domain: Life Science

Unit type: Core

Student role: Biomedical students

Phenomenon: Darwin’s bark spider offspring have different silk flexibility traits, even though they have the same parents.    

Download unit guide

An illustration of a whale with jellyfish and turtles from Amplify Science
Populations and Resources

Domain: Life Science

Unit type: Core

Student role: Biologists

Phenomenon: The size of the moon jelly population in Glacier Sea has increased.    

Download unit guide

Low-poly landscape with trees and mushrooms. A fox sniffs the ground, a rabbit sits nearby, and mountains and sun are in the background.
Matter and Energy in Ecosystems

Domain: Life Science

Unit type: Core

Student role: Ecologists

Phenomenon: What caused the mysterious crash of a biodome ecosystem?    

Download unit guide

Four low-poly dinosaurs with missing body sections are standing in a row; one is yellow, and the others are green. They have purple spikes and red patches on their bodies.
Natural Selection

Domain: Life Science

Unit type: Core

Student role: Biologists

Phenomenon: The newt population in Oregon State Park has become more poisonous over time.    

Download unit guide

Red geometric background with icons including a mosquito, DNA strand, bar chart, and world map inside a hexagon.
Natural Selection Engineering Internship

Domain: Life Science

Unit type: Engineering internship

Student role: Clinical engineers

Phenomenon: Designing malaria treatment plans that use different combinations of drugs can reduce drug resistance development while helping malaria patients.  

Two giant tortoises with long necks stand near water; one tortoise feeds on leaves from a tree while the other is near dense vegetation.
Evolutionary History

Domain: Life Science

Unit type: Core

Student role: Paleontologists

Phenomenon: A mystery fossil at the Natural History Museum has similarities with both wolves and whales.    

Download unit guide

Two people climbing rocky terrain; illustrations show a hiking boot and a belt with gear.
Harnessing Human Energy

Domain: Physical Science

Unit type: Launch

Student role: Energy scientists

Phenomenon: Rescue workers can use their own human kinetic energy to power the electrical devices they use during rescue missions.    

Illustration of a futuristic space station with large solar panels, orbiting in deep space, emitting a blue glow from its propulsion system.
Force and Motion

Domain: Physical Science

Unit type: Core

Student role: Physicists

Phenomenon: The asteroid sample-collecting pod failed to dock at the space station as planned.    

Download unit guide

Green geometric background with a hexagonal emblem containing a parachute icon, ruler, bandage, and stacked layers on a gradient pattern.
Force and Motion Engineering Internship

Domain: Physical Science

Unit type: Engineering internship

Student role: Mechanical engineering interns

Phenomenon: Designing emergency supply delivery pods with different structures can maintain the integrity of the supply pods and their contents. 

Illustration of a roller coaster filled with people, hands raised, going down a steep track against a bright blue sky with clouds.
Magnetic Fields

Domain: Physical Science

Unit type: Core

Student role: Physicists

Phenomenon: During a test launch, a spacecraft traveled much faster than expected.    

Illustration of a person in a red hat and fur-lined coat with eyes closed, surrounded by large orange circles on a dark background.
Thermal Energy

Domain: Physical Science

Unit type: Core

Student role: Thermal scientists

Phenomenon: One of two proposed heating systems for Riverdale School will best heat the school.    

Download unit guide

Ilustración que muestra las etapas de fusión de una paleta de naranja: entera, parcialmente derretida, más derretida y casi derretida por completo, con palitos de madera, sobre un fondo morado.
Phase Change

Domain: Physical Science

Unit type: Core

Student role: Chemists

Phenomenon: A methane lake on Titan no longer appears in images taken by a space probe two years apart.    

Download unit guide

Green geometric graphic featuring icons: a baby, thermometer, layers, medical alert, and a flame.
Phase Change Engineering Internship

Domain: Physical Science

Unit type: Engineering internship

Student role: Chemical engineering interns

Phenomenon: Designing portable baby incubators with different combinations of phase change materials can keep babies at a healthy temperature.    

Obra de arte digital abstracta que presenta numerosos círculos rojos y grises superpuestos sobre un fondo dividido de azul y violeta claro, creando una composición dinámica y enérgica.
Chemical Reactions

Domain: Physical Science

Unit type: Core

Student role: Forensic chemists

Phenomenon: A mysterious brown substance has been detected in the tap water of Westfield.    

Download unit guide

An illustration from the Light Waves unit
Light Waves

Domain: Physical Science

Unit type: Core

Student role: Spectroscopists

Phenomenon: The rate of skin cancer is higher in Australia than in other parts of the world.    

Download unit guide

Resources

Pilot support brochure for 6–8 (Domain)

See how we customized our instructional sequence to fully support the Utah SEEd…

Unit phenomena for 6–8(Domain)

Take a closer look at the unit phenomena featured in each grade level.

What’s so phenomenal about phenomena?

Learn actionable strategies that will help you implement 3-D teaching and learni…

Un maestro se encuentra al frente de un salón de clases, explicando una lección que se muestra en una pantalla. Los estudiantes se sientan en sus escritorios y algunos levantan la mano.

Planning Guide for grades 6–8 (Domain)

Check out these tips for planning to teach.

Active reading in 6–8

Learn how we support students in learning how to interact with scientific texts….

Investigations for 6–8(Domain)

Explore the types of investigations that take place in middle school classrooms….

A laptop screen displaying a map with three ecosystem options, each illustrated by different animal icons and accompanied by relevant data lists.

Sims for 4–8

Take a closer look at the digital simulations included at each grade level.

Approaches to assessment in 6–8

Learn about our middle school embedded assessments.

Welcome to Amplify Science 6–8!

Amplify Science is an engaging core curriculum designed for three-dimensional, phenomena-based learning.

With Amplify Science, Oregon students don’t just passively learn about science concepts. Instead, they take on the role of scientists and engineers to actively investigate and figure out real-world phenomena. They do this through a blend of cohesive and compelling storylines, hands-on investigations, collaborative discussions, literacy-rich activities, and interactive digital tools.

Two students, one black and one asian, smiling and studying together at a laptop in a classroom with other students in background.

Publisher presentation

The Lawrence Hall of Science

Developed by the science education experts at UC Berkeley’s Lawrence Hall of Science and the digital learning team at Amplify, our program features:

  • phenomena-based approach where students construct a complex understanding of each unit’s anchor phenomenon.
  • A blend of cohesive storylines, hands-on investigations, rich discussions, literacy-rich activities, and digital tools.
  • Carefully crafted units, chapters, lessons, and activities designed to deliver true 3-dimensional learning.
  • An instructional design that supports all learners in accessing all standards.
Aerial view of the lawrence hall of science at the university of california, berkeley, showcasing the building and surrounding trees with a foggy city backdrop.

Proven to work

A pdf cover from wested titled "learning and literacy development together: initial results from a curriculum study," featuring an adult helping children with schoolwork in a classroom.

WestEd Randomized
Control Trial for Grade 1

Read More

Pdf cover titled "curriculum materials designed for the next generation science standards: initial results from gold standard research trials", published by wested.

WestEd Randomized
Control Trial for Grade 7

Read More

A teacher and students engage in a science activity around a table. The text promotes the Amplify Science K–8 curriculum, highlighting its focus on hands-on learning and real-world problem-solving.

Amplify Science NE
Grades K–5

Read More

Instructional model

The Amplify Science program is rooted in the proven, research-based pedagogy of Do, Talk, Read, Write, Visualize. Here’s how each element works:

Do

First-hand investigations are an important part of any science classroom, and Amplify Science has students getting hands-on in every unit—from building models of protein molecules to experimenting with electrical systems.

Talk

Student-to-student discourse and full-class discussions are an integral part of the program. Students are provided with numerous opportunities to engage in meaningful oral scientific argumentation, all while fostering a collaborative classroom environment.

Read

Students read scientific articles, focusing their reading activities on searching for evidence related to their investigation and, importantly, on asking and recording questions as they read through fascinating texts on 21st-century topics.

Write

Following real-world practices, students write scientific arguments based on evidence they’ve collected, making clear their reasoning about how a given piece of evidence connects to one of several claims.

Visualize

By manipulating digital simulations and using modeling tools to craft visualizations of their thinking— just as real scientists and engineers
do—students take their learning far beyond the confines of what they can physically see in the classroom in an exciting and authentic way.

Program structure

Our cyclical lesson design ensures students receive multiple exposures to concepts through a variety of modalities. As they progress through the lessons within a unit, students build and deepen their understanding, increasing their ability to develop and refine complex explanations of the unit’s phenomenon.

It’s this proven program structure and lesson design that enables Amplify Science to address 100% of the NGSS, and support students in mastering the Oregon Science Standards.

Flowchart depicting a critical thinking process with four circular nodes connected by arrows, each node representing a step: posing a real-world problem, exploring evidence, elaborating concepts, and evaluating claims.

Unit types

While every unit delivers three-dimensional learning experiences and engages students in gathering evidence from a rich collection of sources, each unit also serves a unique instructional purpose.

In grades 6–8:

  • One unit is a launch unit.
  • Three units are core units.
  • Two units are engineering internships.

Launch units are the first units taught in each year of Amplify Science. The goal of the Launch unit is to introduce students to norms, routines, and practices that will be built on throughout the year, including argumentation, active reading, and using the program’s technology. For example, rather than taking the time to explain the process of active reading in every unit in a given year, it is explained thoroughly in the Launch unit, thereby preparing students to read actively in all subsequent units.

Core units establish the context of the unit by introducing students to a real-world problem. As students move through lessons in a Core unit, they figure out the unit’s anchoring phenomenon, gain an understanding of the unit’s disciplinary core ideas and science and engineering practices, and make linkages across topics through the crosscutting concepts. Each Core unit culminates with a Science Seminar and final writing activity.

Engineering Internship units invite students to design solutions for real-world problems as interns for a fictional company called Futura. Students figure out how to help those in need, from tsunami victims in Sri Lanka to premature babies, through the application of engineering practices. In the process, they apply and deepen their learning from Core units.

Unit sequence

Our lessons follow a structure that is grounded in regular routines while still being flexible enough to allow for a variety of learning experiences.

In fact, our multi-modal instruction offers more opportunities for students to construct meaning, and practice and apply concepts than any other program. What’s more, our modular design means our units can be flexibly arranged to support your instructional goals.

Three columns listing education curriculum topics for grades 6, 7, and 8, focusing on science themes such as microbiomes, mars geology, and harnessing human energy.

Program components

Available digitally and in print, our unit-specific reference guides are chock full of helpful resources, including scientific background knowledge, planning information and resources, color-coded 3D Statements, detailed lesson plans, tips for delivering instruction, and differentiation strategies.

Amplify Science TG

Hands-on learning is an essential part of Amplify Science, and is integrated into every unit. Students actively participate in science, playing the roles of scientists and engineers as they gather evidence, think critically, solve problems, and develop and defend claims about the world around them. Every unit includes hands-on investigations that are critical to achieving the unit’s learning goals.

A young person wearing gloves looks through a microscope at a table with laboratory supplies, including bottles, slides, and a tray, against a plain blue background.

More hands-on with Flextensions:
Hands-on Flextensions are additional, optional investigations that are included at logical points in the learning progression and give students an opportunity to dig deeper if time permits. These activities offer teachers flexibility to choose to dedicate more time to hands-on learning. Materials referenced in Hands-on Flextension activities will either be included in the unit kit or are easily sourced. Supporting resources such as student worksheets will be included as downloadable PDF files.

Assorted office and household items displayed on a white background, including rubber bands, binder clips, cardboard, and sports balls.

Our digital Simulations and Practice Tools are powerful resources for exploration, data collection, and student collaboration. They allow students the ability to explore scientific concepts that might otherwise be invisible or impossible to see with the naked eye.

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

In grades 6–8, one copy of the Student Investigation Notebook is included in each unit’s materials kit for use as a blackline master. Each notebook is also available as a downloadable PDF on the Unit Guide page of the digital Teacher’s Guide.

Two booklets titled "El clima cambiante de la Tierra: la desaparición del hielo" and "Earth’s Changing Climate: Vanishing Ice" with landscape illustrations on the covers.

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.

Amplify Science Classroom Slides

Full coverage of the Oregon Science Standards

Amplify Science was designed from the ground up to meet the Next Generation Science Standards (NGSS). As such, it aligns to the Oregon Science Standards, which were also borne out of the NGSS.

The guidance below is meant to provide support for integrating additional activities that support full coverage of Oregon’s standards. Organized by grade level, each section below will outline:

  • Additional activities that support 100% alignment to the Oregon Science Standards.
  • The standard being addressed with the activities.
  • The recommended placement of the activities within a specific Amplify Science unit.
  • PDFs of any accompanying materials that are necessary to implement the activities.

Activity Title: Meet a Scientist Who Changed How We Think About Brain Cells

About this activity: In this activity, students read a short article about a scientist who studied the nervous system.

Recommended placement: Metabolism unit, Lesson 3.2

Materials:

Instructions: Download the PDF “Meet a Scientist Who Changed How We Think About Brain Cells” above and remind students of the Active Reading guidelines. Before students read the article, invite them to share prior experiences. Then have students complete the copymaster above.

Activity Title: Meet a Scientist Who Studies Underwater Currents

About this activity: In this activity, students read a short article about a scientist who studies ocean currents.

Recommended placement: Oceans, Atmosphere, and Climate unit, Lesson 2.1

Materials:

Instructions: Download the PDF “Meet a Scientist Who Studies Underwater Currents” above and remind students of the Active Reading guidelines. Before students read the article, invite them to share prior experiences. Then have students complete the copymaster above.

Activity Title: Meet a Scientist Who Studies How the Environment Affects Our Traits

About this activity: In this activity, students read two short articles, one about current research on genes and proteins, and one about a scientist who is studying how the environment can affect our traits.

Recommended placement: Traits and Reproduction unit, Lesson 2.4

Materials:

Instructions: Download the PDF “Meet a Scientist Who Studies How the Environment Affects Our Traits” above and remind students of the Active Reading guidelines. Before students read the article, invite them to share prior experiences. Then have students complete the copymaster above.

Activity Title: Who Becomes a Space Scientist?

About this activity: In this activity, Students read a short article about a scientist who studies space.

Recommended placement: Geology on Mars unit, Lesson 3.1

Materials:

Instructions: Download the PDF “Who Becomes a Space Scientist?” above and remind students of the Active Reading guidelines. Before students read the article, invite them to share prior experiences. Then have students complete the copymaster above.

Activity Title: Meet a Scientist Who Studies How Plants Find Water Underground

About this activity: In this activity, students read a short article about a scientist who studies how plants’ roots get water.

Recommended placement: Matter and Energy in Ecosystems unit, Lesson 1.6

Materials:

Instructions: Download the PDF “Meet a Scientist Who Studies How Plants Find Water Underground” above and remind students of the Active Reading guidelines. Before students read the article, invite them to share prior experiences. Then have students complete the copymaster above.

Activity Title: Bringing Back the Buffalo

About this activity: In this activity, students change one competing population to try to decrease the other in the Sim, and read a short article about a scientist who studies buffalo.

Recommended placement: Populations and Resources unit, Lesson 3.2

Materials:

Instructions: Download the PDF “Bringing Back the Buffalo” above and remind students of the Active Reading guidelines. Before students read the article, invite them to share prior experiences. Then have students complete the copymaster above.

Activity Title: Rereading “A Continental Puzzle”

About this activity: In this activity, students reread “A Continental Puzzle” and think about how patterns were helpful to Wegener’s work.

Recommended placement: Plate Motion unit, Lesson 3.2

Materials:

Instructions: Direct students back to “A Continental Puzzle” above and remind students of the Active Reading guidelines. Before students re-read the article, invite them to share prior experiences. Then have students complete the copymaster above.

Activity Title: Meet a Scientist Who Studies Variation in Monkey Populations

About this activity: In this activity, students read a short article about a scientist who studies variation of traits in monkey populations.

Recommended placement: Natural Selection unit, Lesson 1.6

Materials:

Instructions: Download the PDF “Meet a Scientist Who Studies Variation in Monkey Populations” above and remind students of the Active Reading guidelines. Before students read the article, invite them to share prior experiences. Then have students complete the copymaster above.

Activity Title: Extinctions and Human Impacts

About this activity: The purpose of this lesson is for students to see how increases in human population and consumption of natural resources can negatively impact Earth’s systems.

Recommended placement: Natural Selection unit, Lesson 4.5

Materials:

Instructions: Download the PDF “Extinctions and Human Impacts” above and remind students of the Active Reading guidelines. Before students read the article, invite them to share prior experiences. Then have students complete the copymaster above.

Activity Title: Steno and the Shark

About this activity: In this activity, students read a short article about Nicolas Steno, a scientist from the 1600s whose studies of fossilized sharks’ teeth embedded in rock layers laid the foundation for the modern understanding of stratigraphy.

Recommended placement: Evolutionary History unit, Lesson 2.4

Materials:

Instructions: Download the PDF “Steno and the Shark” above and remind students of the Active Reading guidelines. Before students read the article, invite them to share prior experiences. Then have students complete the copymaster above.

Activity Title: Scale in the Solar System

About this activity: In this activity, students read and annotate the articles “Scale in the Solar System” and “The Solar System Is Huge.”

Recommended placement: Earth, Moon, and Sun unit, Lesson 1.2

Materials:

Instructions: Download the PDF “Scale in the Solar System” above and remind students of the Active Reading guidelines. Before students read the article, invite them to share prior experiences. Then have students complete the copymaster above.

Explore your print samples

With your Amplify Science print samples, you’ll find unit-specific Teacher’s References Guides and Student Investigation Notebooks for each grade level.

A note about the Teacher’s Reference Guides:

It’s important that your committee sees the full breadth and depth of our instruction. For that reason, we provided a copy of each of our unit-specific Teacher Reference Guides.

Rest assured that teachers do not use these robust reference guides for day-to-day teaching. For that, we have a hands-free TG!

Three laptop screens displaying educational content on earth's energy system, including diagrams and text annotations.
  • Teacher Reference Guide: Unlike a typical TG that requires a series of supplemental books to support it, our encyclopedic reference guide is chock-full of everything a teacher needs to fully implement our program and the NGSS.
  • Ready-to-Teach Lesson Slides: For daily instruction, teachers need their hands free. That’s why we created ready-to-teach lesson slides for every single lesson. What’s more, they are editable and include suggested teacher talk and point-of-use differentiation and other instructional tips. Click to learn more.

A note about the Materials Kits:

Hands-on learning is at the heart of Amplify Science, and is integrated into every unit. In order to make hands-on learning more manageable for busy teachers, Amplify Science materials are organized into unit-specific kits.

Our unit-specific kits:

  • Include more materials — We give teachers enough materials to support 200 student uses.
  • Are more manageable — Unlike other programs that require large groups of students to share limited sets of materials, our kits include enough to support small groups of 4–5 students.
  • Include supportive videos — Each hands-on activity provides clear instructions for the teacher, with more complex activities supported by video demonstrations and illustrations.

At your request, we did not include our materials kits with our submissions samples. However, we did provide grade-specific lists of all materials included in each kit, which you can also find with the links below.

Access your digital samples

Explore as a teacher

Follow these instructions to explore the Amplify Science digital platform as a teacher.

  • Click the Access Amplify Science Platform button below and bookmark it.
  • Select Log in with Amplify.
  • Enter the username: t.or68sci@tryamplify.net
  • Enter the password: Science5OR
  • Click the Science icon.
  • Click on the Grade Menu in the top center of the screen and select any grade.
  • Select any unit.
Access Amplify Science Platform

To help familiarize yourself with navigating the digital platform, watch the below navigational video.

Explore as a student

Follow these instructions to explore the Amplify Science digital platform as a student.

  • Click the Access Amplify Science Platform button below and bookmark it.
  • Select Log in with Amplify.
  • Enter the username: s.or68sci@tryamplify.net
  • Enter the password: Science5OR
  • Click the Science icon.
  • Click on the Grade Menu in the top center of the screen and select any grade.
  • Select any unit.
Access Amplify Science Platform

Resources to support your review

Welcome, Ohio educators!

Designed from the ground up to teach students to think, read, write, and argue like real scientists and engineers, Amplify Science combines literacy-rich activities with hands-on learning and digital tools to engage students in exploring compelling phenomena in every unit.

Students in a classroom interact with educational technology, featuring a diagram and charts on a screen, while working collaboratively on a laptop.

Overview

Developed by UC Berkeley’s Lawrence Hall of Science, our program features:

  • phenomena-based approach where students construct a more complex understanding of each unit’s anchor phenomenon.
  • A blend of cohesive storylines, hands-on investigations, rich discussions, literacy-rich activities, and digital tools.
  • Newly crafted units, chapters, lessons, and activities designed to deliver true 3-dimensional learning.
  • An instructional design that supports all learners in accessing all standards.

Hear what these educators have to say about the program. >

Approach to literacy

Two young children sit at a classroom table reading a book together, with educational materials spread out in front of them.

[Video] Literacy in action (K–5)

Watch students use scientific text to obtain information and practice reading skills, while using writing prompts to create arguments using evidence.

A student sits at a desk writing with a pencil while focused on his work, with classroom materials visible in the background.

[Video] Literacy in action (6–8)

Watch students use scientific text to obtain information and practice reading skills, while using writing prompts to create arguments using evidence.

A teacher in a green shirt helps a young student with writing at a classroom table, with other students and large numbers visible on the wall in the background.

Literacy-rich science instruction (K–5)

Immersing young students in reading, writing, and arguing like real scientists and engineers.

Two students sit at a table in a classroom, working on an assignment together. Other students are also seated and appear to be engaged in their work. Papers and books are spread out on the tables.

Active Reading in grades 6–8

Engaging middle school students in complex science texts.

Elementary school

Get started by watching this class share what they’re figuring out with Amplify Science. >

In Grades K–3 we recommend the national grade level units of Amplify Science to provide students with the appropriate grade level literacy and background knowledge. Individual units are available to purchase.

When you’re ready:

  1. Find a summary of each unit below including each unit’s student role and anchor phenomenon.
  2. Download some helpful resources to support your review.
  3. Explore the digital Teacher’s Guide by clicking the orange “Review now” button.
An illustration from Needs of Plants and Animals unit

Unit 1

Needs of Plants and Animals

Student role: Scientists

Phenomenon: There are no monarch caterpillars in the Mariposa Grove community garden ever since vegetables were planted.

An illustration from the Pushes and Pulls unit

Unit 2

Pushes and Pulls

Student role: Pinball engineers

Phenomenon: Pinball machines allow people to control the direction and strength of forces on a ball.

Silueta de una estructura de parque infantil contra un cielo azul con nubes y tres soles amarillos.

Unit 3

Sunlight and Weather

Student role: Weather scientists

Phenomenon: Students at one school are too cold during morning recess, while students at another are too hot during afternoon recess.

Illustration of sea turtles swimming among seaweed in the ocean, with a large shark in the background.

Unit 1

Animal and Plant Defenses

Student role: Marine scientists

Phenomenon: Spruce the Sea Turtle will soon be released back into the ocean, where she will survive despite predators.

An illustration from the Light and Sound unit

Unit 2

Light and Sound

Student role: Light and sound engineers

Phenomenon: A puppet show company uses light and sound to depict realistic scenes in puppet shows.

An illustration from the Spinning Earth unit

Unit 3

Spinning Earth

Student role: Sky scientists

Phenomenon: The sky looks different to Sai and his grandma when they talk on the phone at night.

An elephant standing next to a tree uses its trunk to pick a fruit from a branch while more fruit hangs above.

Unit 1

Plant and Animal Relationships

Student role: Plant scientists

Phenomenon: No new chalta trees are growing in the fictional Bengal Tiger Reserve in India.

A hand holds a red bean on a table, while a wooden stick spreads white glue and scattered beans. Also on the table are a white cup and a yellow pen.

Unit 2

Properties of Materials

Student role: Glue engineers

Phenomenon: Different glue recipes result in glues that have different properties.

Ilustración de una costa con acantilados, un edificio de centro recreativo con un techo rojo y un letrero, árboles de hoja perenne, una bandera azul y una playa de arena debajo.

Unit 3

Changing Landforms

Student role: Geologists

Phenomenon: The cliff on which Oceanside Recreation Center is situated appears to be receding.

Una ilustración de un tren de alta velocidad moderno y aerodinámico que viaja por una vía elevada con un paisaje verde de fondo.

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.

An illustration from the Inheritance and Traits unit

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.

An illustration from the Environments and Survival unit

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.

An illustration from the Weather and Climate unit

Unit 4

Weather and Climate

Student role: Meteorologists

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

An illustration from the Energy Conversions unit

Unit 1

Energy Conversions

Student role: System engineers

Phenomenon: The fictional town of Ergstown experiences frequent blackouts. Their electrical system seems to be failing.

An illustration from the Earth's Features unit

Unit 2

Earth’s Features

Student role: Geologists

Phenomenon: A mysterious fossil is discovered in a canyon within the fictional Desert Rocks National Park.

An illustration from the Modeling Matter unit

Unit 3

Modeling Matter

Student role: Food scientists

Phenomenon: Some ingredients dissolve in a salad dressing while others, like oil and vinegar, appear to separate.

An illustration from the Earth System unit

Unit 4

The Earth System

Student role: Water resource engineers

Phenomenon: East Ferris, a city on one side of the fictional Ferris Island, is experiencing a water shortage, while West Ferris is not.

An illustration from the Patterns of Earth and Sky unit

Unit 1

Patterns of Earth and Sky

Student role: Astronomers

Phenomenon: An ancient artifact depicts what we see in the sky at different times of the day, but it appears to be missing a piece.

An illustration from the Vision and Light unit

Unit 2

Vision and Light

Student role: Conservation biologists

Phenomenon: The population of Tokay geckos in a rain forest in the Philippines has decreased since the installation of new highway lights.

An illustration from the Waves, Energy, and Information unit

Unit 3

Waves, Energy, and Information

Student role: Marine scientists

Phenomenon: Mother dolphins in the fictional Blue Bay National Park communicate with their calves despite the distance between them.

An illustration from the Ecosystem Restoration unit

Unit 4

Ecosystem Restoration

Student role: Ecologists

Phenomenon: The jaguars, sloths, and cecropia trees in a reforested section of a Costa Rican rain forest are not growing or thriving.

Middle school

Get started by watching this class share what they’re figuring out with Amplify Science. >

When you’re ready:

  1. Find a summary of each unit below including each unit’s student role and anchor phenomenon.
  2. Download some helpful resources to support your review.
  3. Explore the digital Teacher’s Guide by clicking the orange “Review now” button.
Illustration of a cross-section of Earth showing a volcano near the ocean. Trees, mountains, and clouds are visible above, with subterranean layers below.

CORE

Rock Transformations

Domain: Earth and Space Science

Unit type: Core

Student role: Geologists

Phenomenon: Rock samples from the Great Plains and from the Rocky Mountains — regions hundreds of miles apart — look very different, but have surprisingly similar mineral compositions.

Ilustración que muestra las etapas de fusión de una paleta de naranja: entera, parcialmente derretida, más derretida y casi derretida por completo, con palitos de madera, sobre un fondo morado.

CORE

Phase Change

Domains: Physical Science, Earth and Space Science

Unit type: Core

Student role: Chemists

Phenomenon: A methane lake on Titan no longer appears in images taken by a space probe two years apart.

Green geometric graphic featuring icons: a baby, thermometer, layers, medical alert, and a flame.

ENGINEERING INTERNSHIP

Phase Change Engineering Internship

Domains: Engineering Design, Physical Science

Unit type: Engineering internship

Student role: Chemical engineering interns

Phenomenon: Designing portable baby incubators with different combinations of phase change materials can keep babies at a healthy temperature.

Illustration of a person in a red hat and fur-lined coat with eyes closed, surrounded by large orange circles on a dark background.

CORE

Thermal Energy

Domain: Physical Science

Unit type: Core

Student role: Thermal scientists

Phenomenon: One of two proposed heating systems for Riverdale School will best heat the school.

Abstract art with vibrant colors featuring a yellow silhouette of a person holding a book against a background of geometric shapes, swirling patterns, and bold textures.

LAUNCH

Microbiome

Domain: Life Science

Unit type: Launch

Student role: Microbiological researchers

Phenomenon: The presence of 100 trillion microorganisms living on and in the human body may keep the body healthy.

Abstract artwork of a person's side profile with geometric shapes and colorful patterns flowing from the head, holding a small sledgehammer. A vision chart is visible in the corner.

CORE

Metabolism

Domain: Life Science

Unit type: Core

Student role: Medical researchers

Phenomenon: Elisa, a young patient, feels tired all the time.

Orange abstract background with hexagonal shapes featuring icons of a bar chart, plant, safety vest, test tube, peach, and stethoscope.

ENGINEERING INTERNSHIP

Metabolism Engineering Internship

Domains: Life Science, Engineering Design

Unit type: Engineering internship

Student role: Food engineers

Phenomenon: Designing health bars with different molecular compositions can effectively meet the metabolic needs of patients or rescue workers.

Two people climbing rocky terrain; illustrations show a hiking boot and a belt with gear.

LAUNCH

Harnessing Human Energy

Domains: Physical Science, Earth and Space Science, Engineering Design

Unit type: Launch

Student role: Energy scientists

Phenomenon: Rescue workers can use their own human kinetic energy to power the electrical devices they use during rescue missions.

A girl runs with a colorful kite displaying literacy skills; text reads "Amplify. Science of Reading: A Primer | Part One" on a grassy landscape background.

CODING SCIENCE INTERNSHIP

Coding Science Internship: Coral Restoration (Optional)

Domains: Life Science, Coding Science

Unit type: Coding Science Internship

Student role: Coding science interns

Phenomenon: Implementing a restoration project to improve the health of coral reef populations in Hawaii.

Abstract artwork depicting a bright sun with blue and orange swirling patterns next to green hills under a sky with shades of blue, orange, and red.

CORE

Ocean, Atmosphere, and Climate

Domains: Earth and Space Science, Physical Science

Unit type: Core

Student role: Climatologists

Phenomenon: During El Niño years, the air temperature in Christchurch, New Zealand is cooler than usual.

An illustration from the Weather Patterns unit

CORE

Weather Patterns

Domains: Earth and Space Science, Physical Science

Unit type: Core

Student role: Forensic meteorologists

Phenomenon: In recent years, rainstorms in Galetown have been unusually severe.

An illustration from the Earth's Changing Climate unit

CORE

Earth’s Changing Climate

Domains: Earth and Space Science, Life Science

Unit type: Core

Student role: Climatologists

Phenomenon: The ice on Earth’s surface is melting.

Abstract geometric design in shades of blue and purple featuring a hexagon with icons of a building, wrench, molecules, sun, paint can, and screwdriver.

ENGINEERING INTERNSHIP

Earth’s Changing Climate Engineering Internship

Domains: Earth and Space Science, Engineering Design

Unit type: Engineering internship

Student role: Civil engineers

Phenomenon: Designing rooftops with different modifications can reduce a city’s impact on climate change.

A city skyline at night with a prominent full moon, stars in the sky, and a bridge silhouette on the left.

CORE

Earth, Moon, and Sun

Domains: Earth and Space Science, Physical Science

Unit type: Core

Student role: Astronomers

Phenomenon: An astrophotographer can only take pictures of specific features on the Moon at certain times.

An illustration from the Chemical Reactions unit

CORE

Chemical Reactions

Domains: Physical Science, Life Science, Earth and Space Science

Unit type: Core

Student role: Forensic chemists

Phenomenon: A mysterious brown substance has been detected in the tap water of Westfield.

An illustration from the Light Waves unit

CORE

Light Waves

Domains: Physical Science, Life Science, Earth and Space Science

Unit type: Core

Student role: Spectroscopists

Phenomenon: The rate of skin cancer is higher in Australia than in other parts of the world.

An illustration of a whale with jellyfish and turtles from Amplify Science

CORE

Populations and Resources

Domains: Life Science, Earth and Space Science

Unit type: Core

Student role: Biologists

Phenomenon: The size of the moon jelly population in Glacier Sea has increased.

Low-poly landscape with trees and mushrooms. A fox sniffs the ground, a rabbit sits nearby, and mountains and sun are in the background.

CORE

Matter and Energy in Ecosystems

Domains: Life Science, Earth and Space Science, Physical Science

Unit type: Core

Student role: Ecologists

Phenomenon: The biodome ecosystem has collapsed.

A girl runs with a colorful kite displaying literacy skills; text reads "Amplify. Science of Reading: A Primer | Part One" on a grassy landscape background.

CODING SCIENCE INTERNSHIP

Coding Science Internship: Coral Restoration (Optional)

Domains: Life Science, Coding Science

Unit type: Coding Science Internship

Student role: Coding science interns

Phenomenon: Implementing a restoration project to improve the health of coral reef populations in Hawaii.

A barren, rocky desert landscape with rover tracks leading to a distant vehicle on a hill under a hazy sky.

LAUNCH

Geology on Mars

Domain: Earth and Space Science

Unit type: Launch

Student role: Planetary geologists

Phenomenon: Analyzing data about landforms on Mars can provide evidence that Mars may have once been habitable.

Two prehistoric reptiles with long snouts and tails are near the shore, one on land and one in water, with plants, rocks, and an island in the background.

CORE

Plate Motion

Domain: Earth and Space Science

Unit type: Core

Student role: Geologists

Phenomenon: Mesosaurus fossils have been found on continents separated by thousands of kilometers of ocean, even though the Mesosaurus species once lived all together.

Geometric design featuring a telescope, mountain, sound waves, and cosmic elements on a purple hexagonal background.

ENGINEERING INTERNSHIP

Plate Motion Engineering Internship

Domains: Earth and Space Science, Engineering Design

Unit type: Engineering internship

Student role: Mechanical engineering interns

Phenomenon: Patterns in earthquake data can be used to design an effective tsunami warning system.

Una nave espacial se acerca a una estación espacial modular con paneles solares extendidos en una ilustración ambientada en el espacio.

CORE

Force and Motion

Domain: Physical Science

Unit type: Core

Student role: Physicists

Phenomenon: The asteroid sample-collecting pod failed to dock at the space station as planned.

Green geometric background with a hexagonal emblem containing a parachute icon, ruler, bandage, and stacked layers on a gradient pattern.

ENGINEERING INTERNSHIP

Force and Motion Engineering Internship

Domains: Engineering Design, Physical Science

Unit type: Engineering internship

Student role: Mechanical engineering interns

Phenomenon: Designing emergency supply delivery pods with different structures can maintain the integrity of the supply pods and their contents.

Illustration of a roller coaster filled with people, hands raised, going down a steep track against a bright blue sky with clouds.

CORE

Magnetic Fields

Domain: Physical Science

Unit type: Core

Student role: Physicists

Phenomenon: During a test launch, a spacecraft traveled much faster than expected.

Imagen que muestra un gráfico de arañas de diferentes colores con patrones distintos de patas y cuerpo, incluidas variaciones de color marrón, amarillo y azul. El fondo es una superficie oscura y texturizada.

CORE

Traits and Reproduction

Domain: Life Science

Unit type: Core

Student role: Biomedical students

Phenomenon: Darwin’s bark spider offspring have different silk flexibility traits, even though they have the same parents.

Four low-poly dinosaurs with missing body sections are standing in a row; one is yellow, and the others are green. They have purple spikes and red patches on their bodies.

CORE

Natural Selection

Domains: Life Science, Earth and Space Science

Unit type: Core

Student role: Biologists

Phenomenon: The newt population in Oregon State Park has become more poisonous over time.

Red geometric background with icons including a mosquito, DNA strand, bar chart, and world map inside a hexagon.

ENGINEERING INTERNSHIP

Natural Selection Engineering Internship

Domains: Life Science, Earth and Space Science

Student role: Clinical engineers

Phenomenon: Designing malaria treatment plans that use different combinations of drugs can reduce drug resistance development while helping malaria patients.

Illustration of a cross-section of Earth showing a volcano near the ocean. Trees, mountains, and clouds are visible above, with subterranean layers below.

CORE

Rock Transformations (optional)

Domain: Earth and Space Science

Unit type: Core

Student role: Geologists

Phenomenon: Rock samples from the Great Plains and from the Rocky Mountains — regions hundreds of miles apart — look very different, but have surprisingly similar mineral compositions.

Two giant tortoises with long necks stand near water; one tortoise feeds on leaves from a tree while the other is near dense vegetation.

CORE

Evolutionary History

Domains: Life Science, Earth and Space Science

Unit type: Core

Student role: Paleontologists

Phenomenon: A mystery fossil at the Natural History Museum has similarities with both wolves and whales.

A girl runs with a colorful kite displaying literacy skills; text reads "Amplify. Science of Reading: A Primer | Part One" on a grassy landscape background.

CODING SCIENCE INTERNSHIP

Coding Science Internship: Coral Restoration (Optional)

Domains: Life Science, Coding Science

Unit type: Coding Science Internship

Student role: Coding science interns

Phenomenon: Implementing a restoration project to improve the health of coral reef populations in Hawaii.

Resources to support your review

Select a topic below to explore helpful resources with more information about Amplify Science, the program’s development, and pedagogy.

Two young girls, one with braided hair and the other with blonde hair, smiling and looking at a laptop screen in a classroom.
Four-step educational infographic depicting problem-solving process: engaging with real-world problems, exploring multiple sources, constructing explanations, and applying knowledge to new problems.
Integrated 5e model

Learn how the 5E elements are integrated throughout every unit.

Two children engaged in an animated conversation while sitting at a school desk with laptops and books.
Phenomena and storylines (K–5)

Read more about the real-world phenomena featured in each unit.

Children doing schoolwork at home
Phenomena and storylines (6–8)

Read more about the real-world phenomena featured in each unit.

A screenshot from a video titled "amplify science in action: a week in the..." featuring a smiling woman sitting in a classroom setting.
[Video] Planning in action (K–5)

Watch how easy it is for Amplify Science teachers to prep their 3-D instruction.

A woman smiling and gesturing while speaking, seated in a classroom with computers and educational materials around her, with a paused video screen featuring text about "amplify science.
[Video] Planning in action (6–8)

Watch how easy it is for Amplify Science teachers to prep their 3-D instruction.

Two young children sit at a classroom table, one smiling broadly, during an Amplify Science educational activity.
[Video] Hands-on in action (K–5)

Watch Amplify Science students conduct hands-on investigations.

A student in a classroom uses a dropper to add liquid to clear plastic cups during a science experiment. Other students and lab materials are visible in the background.
[Video] Hands-on in action (6–8)

Watch Amplify Science students conduct hands-on investigations.

Two young girls sit side by side at a desk, looking at a laptop screen and working together in a classroom setting.
[Video] Simulations and modeling tools (K–5)

Watch how students investigate phenomena with the help of digital tools.

Two students sit at a table in a classroom, working on laptops and talking, with other students visible in the background.
[Video] Simulations and modeling tools (6–8)

Watch how students investigate phenomena with the help of digital tools.

A young girl wearing safety goggles stretches a gooey substance from a cup in a kitchen or classroom setting.
Summary of Investigations (K–5) coming soon

Explore the types of investigations that students conduct.

A young person wearing gloves looks through a microscope at a table with laboratory supplies, including bottles, slides, and a tray, against a plain blue background.
Summary of Investigations (6–8) coming soon

Explore the types of investigations that students conduct.

A young boy and girl sitting in a classroom, reading a book together with focused expressions.
Program structure and components (K–5)

Take a closer look at how the program is organized.

Teacher assisting two students working on laptops in a classroom; other students are in the background.
Program structure and components (6–8)

Take a closer look at how the program is organized.

Digital collage of various devices displaying educational content about earth’s energy system, including graphs and text explanations.
[Video] New! Classroom Slides

Learn more about our customizable PowerPoints for every lesson.

A laptop screen displays a writing lesson with prompts and a student's response in Amplify Classwork. The student's answer discusses dangers related to a specific scenario involving a sick child.
Classwork (6–8)

A new, intuitive approach to reviewing student work online.

An adult sits on a couch using a laptop while a child next to them does homework in a notebook.
Remote and hybrid learning guide

Amplify is here to help! Amplify Science will soon feature product enhancements and new resources that will help manage the new landscape of back-to-school 2020.

Educational presentation slides from grade 8 amplify science materials spanish kit, displaying various science topics like geology and biology.
Spanish-language supports

Learn more about the Spanish-language supports in Amplify Science.

students collaborating and using laptops
English Learners

Learn how we make learning accessible for English learners.

Amplify Science California supports you every step of the way on your journey to the California NGSS.
Students needing support

Learn how we make learning accessible for students who need more support.

Teacher using a tablet while conducting an mCLASS reading intervention with three young students seated around a table in a classroom.
Students ready for more

Learn how we make learning more rigorous for students ready for a challenge.

Two boys work together on a laptop while a woman—likely one of their middle school teachers—sits beside them, observing and smiling in a classroom setting.
Accessibility

Read more about text design and accessibility, including embedded Read-Aloud audio.

A teacher discusses educational content in front of a whiteboard while students in the classroom raise their hands eagerly.
Approach to assessment (K–5)

Learn about our embedded formative and summative assessments.

Two students sit at desks writing in notebooks and using laptops in a classroom setting.
Approach to assessment (6–8)

Learn about our embedded formative and summative assessments.

A teacher and a young student looking at a laptop together in a colorful classroom decorated with children's artwork.
NGSS Benchmark assessments

Learn more about the Next Generation Science Standards Benchmark assessments created by Amplify.

A young girl in a classroom gives a thumbs up with both hands, smiling broadly, while other students look on in the background.
NGSS Benchmark assessments

NGSS alignment by performance expectation.

Two students in a classroom, one looking at the camera and the other listening intently, with a whiteboard displaying educational content in the background.
NGSS alignment (6–8)

NGSS alignment by performance expectation.

Ready to explore with digital access and physical samples?

Start your digital review and request physical samples with these three easy steps.

  1. Note these Ohio specific login credentials for your digital access.
    Username: t.ohscience@tryamplify.net
    Password: AmplifyNumber1
  2. Click Review now.
  3. Complete the form and select Log in with Amplify to input the Ohio specific login.
A woman sits at a desk in a classroom, working on a laptop with an open binder and papers in front of her.

Contact an Amplify representative

For any questions, fill out the form to the right and a member of our sales team will reach out to you soon.

Katie Cannon
Senior Account Executive

Casie Rayes
Account executive

Matt Paupore
Senior Account Executive

Welcome, Nebraska educators!

Designed from the ground up for the NGSS to teach students to think, read, write, and argue like real scientists and engineers, Amplify Science combines literacy-rich activities with hands-on learning and digital tools to engage students in exploring compelling phenomena in every unit.

Students in a classroom interact with educational technology, featuring a diagram and charts on a screen, while working collaboratively on a laptop.

Overview

Developed by UC Berkeley’s Lawrence Hall of Science, our program features:

  • phenomena-based approach where students construct a more complex understanding of each unit’s anchor phenomenon.
  • A blend of cohesive storylines, hands-on investigations, rich discussions, literacy-rich activities, and digital tools.
  • Newly crafted units, chapters, lessons, and activities designed to deliver true 3-dimensional learning.
  • An instructional design that supports all learners in accessing all standards.

Hear what these educators have to say about the program. >

Explore your grade level

Get started by watching this class share what they’re figuring out with Amplify Science. >

Then select your grade level below to learn more about how we make this type of rich learning accessible to all students at every grade.

Grades K-5 Grades 6–8

Elementary school

When you’re ready:

  1. Find a summary of each unit below including each unit’s student role and anchor phenomenon.
  2. Download some helpful resources to support your review.
  3. Explore the digital Teacher’s Guide by clicking the orange “Review now” button.
A boy reads a book with an illustrated background featuring a dinosaur skull, the Earth, trees, clouds, and water.
An illustration from Needs of Plants and Animals unit

Unit 1

Needs of Plants and Animals

Student role: Scientists

Phenomenon: There are no monarch caterpillars in the Mariposa Grove community garden ever since vegetables were planted.

An illustration from the Pushes and Pulls unit

Unit 2

Pushes and Pulls

Student role: Pinball engineers

Phenomenon: Pinball machines allow people to control the direction and strength of forces on a ball.

Silueta de una estructura de parque infantil contra un cielo azul con nubes y tres soles amarillos.

Unit 3

Sunlight and Weather

Student role: Weather scientists

Phenomenon: Students at one school are too cold during morning recess, while students at another are too hot during afternoon recess.

Illustration of sea turtles swimming among seaweed in the ocean, with a large shark in the background.

Unit 1

Animal and Plant Defenses

Student role: Marine scientists

Phenomenon: Spruce the Sea Turtle will soon be released back into the ocean, where she will survive despite predators.

An illustration from the Light and Sound unit

Unit 2

Light and Sound

Student role: Light and sound engineers

Phenomenon: A puppet show company uses light and sound to depict realistic scenes in puppet shows.

An illustration from the Spinning Earth unit

Unit 3

Spinning Earth

Student role: Sky scientists

Phenomenon: The sky looks different to Sai and his grandma when they talk on the phone at night.

An elephant standing next to a tree uses its trunk to pick a fruit from a branch while more fruit hangs above.

Unit 1

Plant and Animal Relationships

Student role: Plant scientists

Phenomenon: No new chalta trees are growing in the fictional Bengal Tiger Reserve in India.

A hand holds a red bean on a table, while a wooden stick spreads white glue and scattered beans. Also on the table are a white cup and a yellow pen.

Unit 2

Properties of Materials

Student role: Glue engineers

Phenomenon: Different glue recipes result in glues that have different properties.

Ilustración de una costa con acantilados, un edificio de centro recreativo con un techo rojo y un letrero, árboles de hoja perenne, una bandera azul y una playa de arena debajo.

Unit 3

Changing Landforms

Student role: Geologists

Phenomenon: The cliff on which Oceanside Recreation Center is situated appears to be receding.

Una ilustración de un tren de alta velocidad moderno y aerodinámico que viaja por una vía elevada con un paisaje verde de fondo.

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.

An illustration from the Inheritance and Traits unit

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.

An illustration from the Environments and Survival unit

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.

An illustration from the Weather and Climate unit

Unit 4

Weather and Climate

Student role: Meteorologists

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

An illustration from the Energy Conversions unit

Unit 1

Energy Conversions

Student role: System engineers

Phenomenon: The fictional town of Ergstown experiences frequent blackouts. Their electrical system seems to be failing.

An illustration from the Vision and Light unit

Unit 2

Vision and Light

Student role: Conservation biologists

Phenomenon: The population of Tokay geckos in a rain forest in the Philippines has decreased since the installation of new highway lights.

An illustration from the Earth's Features unit

Unit 3

Earth’s Features

Student role: Geologists


Phenomenon: A mysterious fossil is discovered in a canyon within the fictional Desert Rocks National Park.

An illustration from the Waves, Energy, and Information unit

Unit 4

Waves, Energy, and Information

Student role: Marine scientists

Phenomenon: Mother dolphins in the fictional Blue Bay National Park communicate with their calves despite the distance between them.

An illustration from the Patterns of Earth and Sky unit

Unit 1

Patterns of Earth and Sky

Student role: Astronomers

Phenomenon: An ancient artifact depicts what we see in the sky at different times of the day, but it appears to be missing a piece.

An illustration from the Modeling Matter unit

Unit 2

Modeling Matter

Student role: Food scientists

Phenomenon: Some ingredients dissolve in a salad dressing while others, like oil and vinegar, appear to separate

Illustration of a pixelated green mountain cliff deconstructing into a digital grid, with red dots floating over a tranquil sea and flying white birds.

Unit 3

The Earth System

Student role: Water resource engineers

Phenomenon: East Ferris, a city on one side of the fictional Ferris Island, is experiencing a water shortage, while West Ferris is not.

An illustration from the Ecosystem Restoration unit

Unit 4

Ecosystem Restoration

Student role: Ecologists

Phenomenon: The jaguars, sloths, and cecropia trees in a reforested section of a Costa Rican rain forest are not growing or thriving.

Middle school

When you’re ready:

  1. Find a summary of each unit below including each unit’s student role and anchor phenomenon.
  2. Download some helpful resources to support your review.
  3. Explore the digital Teacher’s Guide by clicking the orange “Review now” button.
A person in a black hoodie smiles while working on a laptop, surrounded by illustrations of rockets, satellites, popsicles, and the Earth.
Abstract art with vibrant colors featuring a yellow silhouette of a person holding a book against a background of geometric shapes, swirling patterns, and bold textures.

LAUNCH

Microbiome

Domain: Life Science

Unit type: Launch

Student role: Microbiological researchers

Phenomenon: The presence of 100 trillion microorganisms living on and in the human body may keep the body healthy.  

Abstract artwork of a person's side profile with geometric shapes and colorful patterns flowing from the head, holding a small sledgehammer. A vision chart is visible in the corner.

CORE

Metabolism

Domain: Life Science

Unit type: Core

Student role: Medical researchers

Phenomenon: Elisa, a young patient, feels tired all the time.  

Orange abstract background with hexagonal shapes featuring icons of a bar chart, plant, safety vest, test tube, peach, and stethoscope.

ENGINEERING INTERNSHIP

Metabolism Engineering Internship

Domains: Life Science, Engineering Design

Unit type: Engineering internship

Student role: Food engineers

Phenomenon: Designing health bars with different molecular compositions can effectively meet the metabolic needs of patients or rescue workers.  

Imagen que muestra un gráfico de arañas de diferentes colores con patrones distintos de patas y cuerpo, incluidas variaciones de color marrón, amarillo y azul. El fondo es una superficie oscura y texturizada.

CORE

Traits and Reproduction

Domain: Life Science

Unit type: Core

Student role: Biomedical students

Phenomenon: Darwin’s bark spider offspring have different silk flexibility traits, even though they have the same parents.  

Illustration of a person in a red hat and fur-lined coat with eyes closed, surrounded by large orange circles on a dark background.

CORE

Thermal Energy

Domain: Physical Science

Unit type: Core

Student role: Thermal scientists

Phenomenon: One of two proposed heating systems for Riverdale School will best heat the school.  

Abstract artwork depicting a bright sun with blue and orange swirling patterns next to green hills under a sky with shades of blue, orange, and red.

CORE

Ocean, Atmosphere, and Climate

Domains: Earth and Space Science, Physical Science

Unit type: Core

Student role: Climatologists

Phenomenon: During El Niño years, the air temperature in Christchurch, New Zealand is cooler than usual.  

An illustration from the Weather Patterns unit

CORE

Weather Patterns

Domains: Earth and Space Science, Physical Science

Unit type: Core

Student role: Forensic meteorologists

Phenomenon: In recent years, rainstorms in Galetown have been unusually severe.  

An illustration from the Earth's Changing Climate unit

CORE

Earth’s Changing Climate

Domains: Earth and Space Science, Life Science

Unit type: Core

Student role: Climatologists

Phenomenon: The ice on Earth’s surface is melting.  

Abstract geometric design in shades of blue and purple featuring a hexagon with icons of a building, wrench, molecules, sun, paint can, and screwdriver.

Engineering Internship

Earth’s Changing Climate Engineering Internship

Domains: Earth and Space Science, Engineering Design

Unit type: Engineering internship

Student role: Civil engineers

Phenomenon: Designing rooftops with different modifications can reduce a city’s impact on climate change.  

A barren, rocky desert landscape with rover tracks leading to a distant vehicle on a hill under a hazy sky.

LAUNCH

Geology on Mars

Domain: Earth and Space Science

Unit type: Launch

Student role: Planetary geologists

Phenomenon: Analyzing data about landforms on Mars can provide evidence that Mars may have once been habitable.  

Two prehistoric reptiles with long snouts and tails are near the shore, one on land and one in water, with plants, rocks, and an island in the background.

CORE

Plate Motion

Domain: Earth and Space Science

Unit type: Core

Student role: Geologists

Phenomenon: Mesosaurus fossils have been found on continents separated by thousands of kilometers of ocean, even though the Mesosaurus species once lived all together.   

Geometric design featuring a telescope, mountain, sound waves, and cosmic elements on a purple hexagonal background.

ENGINEERING INTERNSHIP

Plate Motion Engineering Internship

Domains: Earth and Space Science, Engineering Design

Unit type: Engineering internship

Student role: Mechanical engineering interns

Phenomenon: Patterns in earthquake data can be used to design an effective tsunami warning system.  

Illustration of a cross-section of Earth showing a volcano near the ocean. Trees, mountains, and clouds are visible above, with subterranean layers below.

CORE

Rock Transformations

Domain: Earth and Space Science

Unit type: Core

Student role: Geologists

Phenomenon: Rock samples from the Great Plains and from the Rocky Mountains — regions hundreds of miles apart — look very different, but have surprisingly similar mineral compositions.  

Ilustración que muestra las etapas de fusión de una paleta de naranja: entera, parcialmente derretida, más derretida y casi derretida por completo, con palitos de madera, sobre un fondo morado.

CORE

Phase Change

Domains: Physical Science, Earth and Space Science

Unit type: Core

Student role: Chemists

Phenomenon: A methane lake on Titan no longer appears in images taken by a space probe two years apart.  

Green geometric graphic featuring icons: a baby, thermometer, layers, medical alert, and a flame.

ENGINEERING INTERNSHIP

Phase Change Engineering Internship

Domains: Engineering Design, Physical Science

Unit type: Engineering internship

Student role: Chemical engineering interns

Phenomenon: Designing portable baby incubators with different combinations of phase change materials can keep babies at a healthy temperature.  

An illustration from the Chemical Reactions unit

CORE

Chemical Reactions

Domains: Physical Science, Life Science, Earth and Space Science

Unit type: Core

Student role: Forensic chemists

Phenomenon: A mysterious brown substance has been detected in the tap water of Westfield.   

An illustration of a whale with jellyfish and turtles from Amplify Science

CORE

Populations and Resources

Domains: Life Science, Earth and Space Science

Unit type: Core

Student role: Biologists

Phenomenon: The size of the moon jelly population in Glacier Sea has increased.  

Low-poly landscape with trees and mushrooms. A fox sniffs the ground, a rabbit sits nearby, and mountains and sun are in the background.

CORE

Matter and Energy in Ecosystems

Domains: Life Science, Earth and Space Science, Physical Science

Unit type: Core

Student role: Ecologists

Phenomenon: The biodome ecosystem has collapsed.  

Two people climbing rocky terrain; illustrations show a hiking boot and a belt with gear.

LAUNCH

Harnessing Human Energy

Domains: Physical Science, Earth and Space Science, Engineering Design

Unit type: Launch

Student role: Energy scientists

Phenomenon: Rescue workers can use their own human kinetic energy to power the electrical devices they use during rescue missions.  

Illustration of a futuristic space station with large solar panels, orbiting in deep space, emitting a blue glow from its propulsion system.

CORE

Force and Motion

Domain: Physical Science

Unit type: Core

Student role: Physicists

Phenomenon: The asteroid sample-collecting pod failed to dock at the space station as planned.   

Green geometric background with a hexagonal emblem containing a parachute icon, ruler, bandage, and stacked layers on a gradient pattern.

ENGINEERING INTERNSHIP

Force and Motion Engineering Internship

Domains: Engineering Design, Physical Science

Unit type: Engineering internship

Student role: Mechanical engineering interns

Phenomenon: Designing emergency supply delivery pods with different structures can maintain the integrity of the supply pods and their contents.  

Illustration of a roller coaster filled with people, hands raised, going down a steep track against a bright blue sky with clouds.

CORE

Magnetic Fields

Domain: Physical Science

Unit type: Core

Student role: Physicists

Phenomenon: During a test launch, a spacecraft traveled much faster than expected.  

An illustration from the Light Waves unit

CORE

Light Waves

Domains: Physical Science, Life Science, Earth and Space Science

Unit type: Core

Student role: Spectroscopists

Phenomenon: The rate of skin cancer is higher in Australia than in other parts of the world.   

A city skyline at night with a prominent full moon, stars in the sky, and a bridge silhouette on the left.

CORE

Earth, Moon, and Sun

Domains: Earth and Space Science, Physical Science

Unit type: Core

Student role: Astronomers

Phenomenon: An astrophotographer can only take pictures of specific features on the Moon at certain times.  

Four low-poly dinosaurs with missing body sections are standing in a row; one is yellow, and the others are green. They have purple spikes and red patches on their bodies.

CORE

Natural Selection

Domains: Life Science, Earth and Space Science

Unit type: Core

Student role: Biologists

Phenomenon: The newt population in Oregon State Park has become more poisonous over time.  

Red geometric background with icons including a mosquito, DNA strand, bar chart, and world map inside a hexagon.

ENGINEERING INTERNSHIP

Natural Selection Engineering Internship

Domains: Engineering Design, Life Science

Unit type: Engineering internship

Student role: Clinical engineers

Phenomenon: Designing malaria treatment plans that use different combinations of drugs can reduce drug resistance development while helping malaria patients.   

Two giant tortoises with long necks stand near water; one tortoise feeds on leaves from a tree while the other is near dense vegetation.

CORE

Evolutionary History

Domains: Life Science, Earth and Space Science

Unit type: Core

Student role: Paleontologists

Phenomenon: A mystery fossil at the Natural History Museum has similarities with both wolves and whales.    

Resources to support your review

Select a topic below to explore helpful resources with more information about Amplify Science, the program’s development, and pedagogy.

Dos niñas están sentadas en una mesa, mirando juntas la pantalla de una computadora portátil en un salón de clases. Al fondo se ven estanterías con libros y materiales de clase.
Two children engaged in an animated conversation while sitting at a school desk with laptops and books.
Phenomena and storylines (K–5)

Read more about the real-world phenomena featured in each unit.

Children doing schoolwork at home
Phenomena and storylines (6–8)

Read more about the real-world phenomena featured in each unit.

Four-step educational infographic depicting problem-solving process: engaging with real-world problems, exploring multiple sources, constructing explanations, and applying knowledge to new problems.
Integrated 5e model

Learn how the 5E elements are integrated throughout every unit.

A woman smiling and gesturing while speaking, seated in a classroom with computers and educational materials around her, with a paused video screen featuring text about "amplify science.
[Video] Planning in action (K–5)

Watch how easy it is for Amplify Science teachers to prep their 3-D instruction.

A screenshot from a video titled "amplify science in action: a week in the..." featuring a smiling woman sitting in a classroom setting.
[Video] Planning in action (6–8)

Watch how easy it is for Amplify Science teachers to prep their 3-D instruction.

Two children sitting at a table, one in a yellow shirt and the other in pink, smiling and looking forward.
[Video] Hands-on in action (K–5)

Watch Amplify Science students conduct hands-on investigations.

A boy in a science classroom observes a reaction in a clear cup. Other students and lab materials are in the background.
[Video] Hands-on in action (6–8)

Watch Amplify Science students conduct hands-on investigations.

Two children in school uniforms work together on laptops in a classroom setting, with focus on learning and collaboration.
[Video] Simulations and modeling tools (K–5)

Watch how students investigate phenomena with the help of digital tools.

Students sitting at a table using laptops, engaging in a classroom activity.
[Video] Simulations and modeling tools (6–8)

Watch how students investigate phenomena with the help of digital tools.

A young girl wearing safety goggles stretches a gooey substance from a cup in a kitchen or classroom setting.
Summary of Investigations (K–5)

Explore the types of investigations that students conduct.

A young person wearing gloves looks through a microscope at a table with laboratory supplies, including bottles, slides, and a tray, against a plain blue background.
Summary of Investigations (6–8)

Explore the types of investigations that students conduct.

A young boy and girl sitting in a classroom, reading a book together with focused expressions.
Program structure and components (K–5)

Take a closer look at how the program is organized.

Teacher assisting two students working on laptops in a classroom; other students are in the background.
Program structure and components (6–8)

Take a closer look at how the program is organized.

Digital collage of various devices displaying educational content about earth’s energy system, including graphs and text explanations.
[Video] New! Classroom Slides

Learn more about our customizable PowerPoints for every lesson.

A laptop screen displays a writing lesson with prompts and a student's response in Amplify Classwork. The student's answer discusses dangers related to a specific scenario involving a sick child.
Classwork (6–8)

A new, intuitive approach to reviewing student work online.

students collaborating and using laptops
English Learners

Learn how we make learning accessible for English learners.

Amplify Science California supports you every step of the way on your journey to the California NGSS.
Students needing support

Learn how we make learning accessible for students who need more support.

Teacher using a tablet while conducting an mCLASS reading intervention with three young students seated around a table in a classroom.
Students ready for more

Learn how we make learning more rigorous for students ready for a challenge.

Two young children sit at a table looking at an open book, with other books placed in front of them. A play button is visible over the image.
[Video] Literacy in action (K–5)

Watch students use scientific text to obtain information and practice reading skills, while using writing prompts to create arguments using evidence

A student writes in a notebook, holding a pencil, focused on the task.
[Video] Literacy in action (6–8)

Watch students use scientific text to obtain information and practice reading skills, while using writing prompts to create arguments using evidence.

A teacher in a green shirt helps a young student with writing at a classroom table, with other students and large numbers visible on the wall in the background.
Literacy-rich science instruction (K–5)

Immersing young students in reading, writing, and arguing like real scientists and engineers.

Two students sit at a table in a classroom, working on an assignment together. Other students are also seated and appear to be engaged in their work. Papers and books are spread out on the tables.
Active Reading in grades 6–8

Engaging middle school students in complex science texts.

Two boys work together on a laptop while a woman—likely one of their middle school teachers—sits beside them, observing and smiling in a classroom setting.
Accessibility

Read more about text design and accessibility, including embedded Read-Aloud audio.

A teacher discusses educational content in front of a whiteboard while students in the classroom raise their hands eagerly.
Approach to assessment (K–5)

Learn about our embedded formative and summative assessments.

Two students sit at desks writing in notebooks and using laptops in a classroom setting.
Approach to assessment (6–8)

Learn about our embedded formative and summative assessments.

A teacher and a young student looking at a laptop together in a colorful classroom decorated with children's artwork.
NGSS Benchmark assessments

Learn more about the Next Generation Science Standards Benchmark assessments created by Amplify.

A young girl in a classroom gives a thumbs up with both hands, smiling broadly, while other students look on in the background.
NGSS alignment (K–5)

NGSS alignment by performance expectation.

Two students in a classroom, one looking at the camera and the other listening intently, with a whiteboard displaying educational content in the background.
NGSS alignment (6–8)

NGSS alignment by performance expectation.

Two children sit at a table with Chromebooks, facing each other and talking, in a classroom with books and storage bins in the background.
Remote and hybrid learning guide

Amplify is here to help! Amplify Science will soon feature product enhancements and new resources that will help manage the new landscape of back-to-school 2020.

Educational presentation slides from grade 8 amplify science materials spanish kit, displaying various science topics like geology and biology.
Spanish-language supports

Learn more about the Spanish-language supports in Amplify Science.

Ready to start exploring with digital access?

A woman sits at a desk in a classroom, working on a laptop with an open binder and papers in front of her.

Contact an Amplify representative

Laina Armbruster
larmbruster@amplify.com
(602) 791-4135

Bob McCarty
rmccarty@amplify.com
(435) 655-1731

Kristin McDonald
kmcdonald@amplify.com
(515) 240-0244

Review Materials

Teacher Reference Guides

It’s important that your committee sees the full breadth and depth of our instruction. For that reason, we provided a copy of each of our unit-specific Teacher Reference Guides. Before you panic, rest assured that teachers do not use these robust reference guides for day-to-day teaching. For that, we have a hands-free TG!

Amplify Science lesson slides

  • Teacher Reference Guide: Unlike a typical TG that requires a series of supplemental books to support it, our encyclopedic reference guide is chock-full of everything a teacher needs to fully implement our program and the NGSS.
  • Ready-to-Teach Digital Lessons: For daily instruction, teachers need their hands free. That’s why we created ready-to-teach lesson slides for every single lesson What’s more, they are editable and include suggested teacher talk and point-of-use differentiation and other instructional tips. Read this help article to learn more.

Hands-on kits

Every unit of our program includes a dedicated hands-on materials kit. Due to the amount of materials involved, we provided your committee two sample kits per grade level. Our unit-specific kits make material management easy for teachers—they grab the tub they need and then put it all back with ease. Plus, items needed for multiple units are duplicated and found in each tub.

Amplify Science hands-on kits

Our unit-specific kits:

  • Include more materials — We give you enough non-consumable materials to support 200 student uses.
  • Are more manageable — Unlike other programs that require large groups of students to share limited sets of materials, our kits include enough to support small groups of 4–5 students.
  • Include supportive videos — Each hands-on activity provides clear instructions for the teacher, with more complex activities supported by video demonstrations and illustrations.

Overview

Developed by UC Berkeley’s Lawrence Hall of Science, our program features:

  • A phenomena-based approach where students construct a more complex understanding of each unit’s anchor phenomenon.
  • A blend of cohesive storylines, hands-on investigations, rich discussions, literacy-rich activities, and digital tools.
  • Cohesive units, chapters, lessons, and activities designed to deliver true 3-dimensional learning.
  • An instructional design that supports all learners in accessing all standards.

 

Hands-on investigations

Literacy integration

Simulations and modeling tools

Classroom discussions

EdReports All-Green

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

Read the review on EdReports.

Program structure

Our cyclical lesson design ensures students receive multiple exposures to concepts through a variety of modalities.

As they progress through the lessons within a unit, students build and deepen their understanding, increasing their ability to develop and refine complex explanations of the unit’s phenomenon. It’s this proven program structure and lesson design that enables Amplify Science to address 100% of the NGSS in fewer days than other programs.

Navigating an Engineering Internship (Part 2)

This Part 2 video demonstrates how to use the Futura Workspace to manage the immersive experience of the Engineering Internship units. This includes guidance on how to create student groups, how to review student work, and how to send students targeted feedback on their designs.

Unit sequence

Our lessons follow a structure that is grounded in regular routines while still being flexible enough to allow for a variety of learning experiences.

In fact, our multi-modal instruction offers more opportunities for students to construct meaning, and practice and apply concepts than any other program. What’s more, our modular design means our units can be flexibly arranged to support your instructional goals.

Unit 1

Microbiome

Domain: Life Science

Unit type: Launch

Student role: Microbiological researchers

Phenomenon: The presence of 100 trillion microorganisms living on and in the human body may keep the body healthy.  

Unit 2

Metabolism

Domain: Life Science

Unit type: Core

Student role: Medical researchers

Phenomenon: Elisa, a young patient, feels tired all the time.  

See how this unit works

Unit 3

Metabolism Engineering Internship

Domains: Life Science, Engineering Design

Unit type: Engineering internship

Student role: Food engineers

Phenomenon: Designing health bars with different molecular compositions can effectively meet the metabolic needs of patients or rescue workers.  

Unit 4

Traits and Reproduction

Domain: Life Science

Unit type: Core

Student role: Biomedical students

Phenomenon: Darwin’s bark spider offspring have different silk flexibility traits, even though they have the same parents.  

See how this unit works

Unit 5

Thermal Energy

Domain: Physical Science

Unit type: Core

Student role: Thermal scientists

Phenomenon: One of two proposed heating systems for Riverdale School will best heat the school.  

See how this unit works   

Unit 6

Ocean, Atmosphere, and Climate

Domains: Earth and Space Science, Physical Science

Unit type: Core

Student role: Climatologists

Phenomenon: During El Niño years, the air temperature in Christchurch, New Zealand is cooler than usual.  

Unit 7

Weather Patterns

Domains: Earth and Space Science, Physical Science

Unit type: Core

Student role: Forensic meteorologists

Phenomenon: In recent years, rainstorms in Galetown have been unusually severe.  

See how this unit works

Unit 8

Earth’s Changing Climate

Domains: Earth and Space Science, Life Science

Unit type: Core

Student role: Climatologists

Phenomenon: The ice on Earth’s surface is melting.  

See how this unit works

Unit 9

Earth’s Changing Climate Engineering Internship

Domains: Earth and Space Science, Engineering Design

Unit type: Engineering internship

Student role: Civil engineers

Phenomenon: Designing rooftops with different modifications can reduce a city’s impact on climate change.  

Unit 1

Geology on Mars

Domain: Earth and Space Science

Unit type: Launch

Student role: Planetary geologists

Phenomenon: Analyzing data about landforms on Mars can provide evidence that Mars may have once been habitable.  

Unit 2

Plate Motion

Domain: Earth and Space Science

Unit type: Core

Student role: Geologists

Phenomenon: Mesosaurus fossils have been found on continents separated by thousands of kilometers of ocean, even though the Mesosaurus species once lived all together.  

See how this unit works

Unit 3

Plate Motion Engineering Internship

Domains: Earth and Space Science, Engineering Design

Unit type: Engineering internship

Student role: Mechanical engineering interns

Phenomenon: Patterns in earthquake data can be used to design an effective tsunami warning system.    

Unit 4

Rock Transformations

Domain: Earth and Space Science

Unit type: Core

Student role: Geologists

Phenomenon: Rock samples from the Great Plains and from the Rocky Mountains — regions hundreds of miles apart — look very different, but have surprisingly similar mineral compositions.   

See how this unit works

Unit 5

Phase Change

Domains: Physical Science, Earth and Space Science

Unit type: Core

Student role: Chemists

Phenomenon: A methane lake on Titan no longer appears in images taken by a space probe two years apart.  

See how this unit works

Unit 6

Phase Change Engineering Internship

Domains: Engineering Design, Physical Science

Unit type: Engineering internship

Student role: Chemical engineering interns

Phenomenon: Designing portable baby incubators with different combinations of phase change materials can keep babies at a healthy temperature.  

Unit 7

Chemical Reactions

Domains: Physical Science, Life Science, Earth and Space Science

Unit type: Core

Student role: Forensic chemists

Phenomenon: A mysterious brown substance has been detected in the tap water of Westfield.  

See how this unit works

Unit 8

Populations and Resources

Domains: Life Science, Earth and Space Science

Unit type: Core

Student role: Biologists

Phenomenon: The size of the moon jelly population in Glacier Sea has increased.  

See how this unit works  

Unit 9

Matter and Energy in Ecosystems

Domains: Life Science, Earth and Space Science, Physical Science

Unit type: Core

Student role: Ecologists

Phenomenon: The biodome ecosystem has collapsed.  

See how this unit works 

Unit 1

Harnessing Human Energy

Domains: Physical Science, Earth and Space Science, Engineering Design

Unit type: Launch

Student role: Energy scientists

Phenomenon: Rescue workers can use their own human kinetic energy to power the electrical devices they use during rescue missions.   

Unit 2

Force and Motion

Domain: Physical Science

Unit type: Core

Student role: Physicists

Phenomenon: The asteroid sample-collecting pod failed to dock at the space station as planned.  

See how this unit works

Unit 3

Force and Motion Engineering Internship

Domains: Engineering Design, Physical Science

Unit type: Engineering internship

Student role: Mechanical engineering interns

Phenomenon: Designing emergency supply delivery pods with different structures can maintain the integrity of the supply pods and their contents.  

Unit 4

Magnetic Fields

Domain: Physical Science

Unit type: Core

Student role: Physicists

Phenomenon: During a test launch, a spacecraft traveled much faster than expected.  

Unit 5

Light Waves

Domains: Physical Science, Life Science, Earth and Space Science

Unit type: Core

Student role: Spectroscopists

Phenomenon: The rate of skin cancer is higher in Australia than in other parts of the world.  

See how this unit works

Unit 6

Earth, Moon, and Sun

Domains: Earth and Space Science, Physical Science

Unit type: Core

Student role: Astronomers

Phenomenon: An astrophotographer can only take pictures of specific features on the Moon at certain times.  

Unit 7

Natural Selection

Domains: Life Science, Earth and Space Science

Unit type: Core

Student role: Biologists

Phenomenon: The newt population in Oregon State Park has become more poisonous over time.  

See how this unit works

Unit 8

Metabolism Engineering Internship

Domains: Life Science, Engineering Design

Unit type: Engineering internship

Student role: Food engineers

Phenomenon: Designing health bars with different molecular compositions can effectively meet the metabolic needs of patients or rescue workers.  

Unit 9

Evolutionary History

Domains: Life Science, Earth and Space Science

Unit type: Core

Student role: Paleontologists

Phenomenon: A mystery fossil at the Natural History Museum has similarities with both wolves and whales.    

See how this unit works

Access program

Watch the video to the right plus the ones below showing you how to navigate our digital platform. When you’re ready, follow the instructions below to log into our live demo account.

  • Click the orange button below to access the platform.
  • To explore as a teacher, enter this username (t1.washoemssci@demo.tryamplify.net) and this password ( Amplify1-washoemssci).
  • To explore as a student, enter this username (s1.washoemssci@demo.tryamplify.net) and this password ( Amplify1-washoemssci).
  • Choose your grade level from the drop-down menu.

 

Access the digital platform now

Navigating an Engineering Internship (Part 1)

This Part 1 video demonstrates how Engineering Internship units invite students to design solutions for real-world problems as interns for a fictional company called Futura. In the process, they apply and deepen their learning from Core units.

Navigating an Engineering Internship (Part 2)

This Part 2 video demonstrates how to use the Futura Workspace to manage the immersive experience of the Engineering Internship units. This includes guidance on how to create student groups, how to review student work, and how to send students targeted feedback on their designs.

Navigating our reporting tools

Teachers of Amplify Science grades 6–8 have access to a feature called Reporting. When unit assessments are administered digitally, the Reporting tool enables teachers to analyze student performance on the unit assessments.

Differentiation post-assessment

Every core unit of Amplify Science 6–8 features a formal formative assessment opportunity at the mid-way point, or Critical Juncture, of the unit, which provides an important opportunity for differentiation.

Resources

Two middle school girls use a Student Investigation Notebook to take on the role of scientists and engineers

Course structure for 6–8

Take a closer look at how the program is organized.

Unit phenomena for 6–8

Take a closer look at the middle school unit phenomena featured in each grade level.
A young person wearing gloves looks through a microscope at a table with laboratory supplies, including bottles, slides, and a tray, against a plain blue background.

Investigations for 6–8

Explore the types of investigations that take place in middle school classrooms.
Amplify Science California supports 3-D learning with more materials than any other program.

Kit-provided components for 6–8

See what components come in our materials kits!

Teacher-provided components for 6–8

See a list of typical classroom items provided by teachers.
A laptop screen displaying a map with three ecosystem options, each illustrated by different animal icons and accompanied by relevant data lists.

Sims for 4–8

Take a closer look at the digital Simulations included at each grade level.

Active reading in 6–8

Learn how we support students in learning how to interact with scientific texts.
Estudiantes sentados en escritorios, concentrados en escribir en cuadernos y trabajar en computadoras portátiles en un salón de clases.

Approaches to assessment in 6–8

Learn about our middle school embedded assessments.

A closer look at grades 6–8

Amplify Science California is based on the latest research on teaching and learning and helps teachers deliver rigorous and riveting lessons through hands-on investigations, literacy-rich activities, and interactive digital tools that empower students to think, read, write, and argue like real scientists.

In the 6–8 classroom, this looks like students:

  • Collecting evidence from a variety of sources.
  • Making sense of evidence in a variety of ways.
  • Formulating convincing scientific arguments.

Is your school implementing the domain model? Click here.

Collage of four images showing children engaged in educational activities such as conducting experiments and crafting in a classroom setting.
A four-step process diagram with icons: spark a real-world problem, explore sources, explain and elaborate, and evaluate claims, all linking to engage with cohesive storylines.

Program structure

Our cyclical lesson design ensures students receive multiple exposures to concepts through a variety of modalities. As they progress through the lessons within a unit, students build and deepen their understanding, increasing their ability to develop and refine complex explanations of the unit’s phenomenon.

It’s this proven program structure and lesson design that enables Amplify Science California to teach less, but achieve more. Rather than asking teachers to wade through unnecessary content, we designed our 6–8 program to address 100% of the California NGSS in fewer lessons than other programs.

Scope and sequence

Every year our grades 6–8 sequence consists of 9 units, with each unit containing 10–19 lessons. Lessons are written to last a minimum of 45-minutes, though teachers can expand or contract the timing to meet their needs.

Chart displaying educational science topics for grades 6 to 8, categorized by grade level, duration in days, and number of classes. Includes subjects like microbiome, geology, and natural selection.

Unit types

Each unit delivers three-dimensional learning experiences and engages students in gathering evidence from a rich collection of sources, while also serving a unique purpose.

In grades 6–8, there are three types of units:

  • One unit is a launch unit.
  • Three units are core units.
  • Two units are engineering internships.
Launch units

Launch units are the first units taught in each year of Amplify Science California. The goal of the Launch unit is to introduce students to norms, routines, and practices that will be built on throughout the year, including argumentation, active reading, and using the program’s technology. For example, rather than taking the time to explain the process of active reading in every unit in a given year, it is explained thoroughly in the Launch unit, thereby preparing students to read actively in all subsequent units.

Core units

Core units establish the context of the unit by introducing students to a real-world problem. As students move through lessons in a Core unit, they figure out the unit’s anchoring phenomenon, gain an understanding of the unit’s disciplinary core ideas and science and engineering practices, and make linkages across topics through the crosscutting concepts. Each Core unit culminates with a Science Seminar and final writing activity.

Engineering Internship units

Engineering Internship units invite students to design solutions for real-world problems as interns for a fictional company called Futura. Students figure out how to help those in need, from tsunami victims in Sri Lanka to premature babies, through the application of engineering practices. In the process, they apply and deepen their learning from Core units.

Units at a glance

Abstract art with vibrant colors featuring a yellow silhouette of a person holding a book against a background of geometric shapes, swirling patterns, and bold textures.
Microbiome

Domain: Life Science

Unit type: Launch

Student role: Microbiological researchers

Phenomenon: The presence of 100 trillion microorganisms living on and in the human body may keep the body healthy.  

Abstract artwork of a person's side profile with geometric shapes and colorful patterns flowing from the head, holding a small sledgehammer. A vision chart is visible in the corner.
Metabolism

Domain: Life Science

Unit type: Core

Student role: Medical researchers

Phenomenon: Elisa, a young patient, feels tired all the time.  

Download unit guide

Orange abstract background with hexagonal shapes featuring icons of a bar chart, plant, safety vest, test tube, peach, and stethoscope.
Metabolism Engineering Internship

Domains: Life Science, Engineering Design

Unit type: Engineering internship

Student role: Food engineers

Phenomenon: Designing health bars with different molecular compositions can effectively meet the metabolic needs of patients or rescue workers.  

Imagen que muestra un gráfico de arañas de diferentes colores con patrones distintos de patas y cuerpo, incluidas variaciones de color marrón, amarillo y azul. El fondo es una superficie oscura y texturizada.
Traits and Reproduction

Domain: Life Science

Unit type: Core

Student role: Biomedical students

Phenomenon: Darwin’s bark spider offspring have different silk flexibility traits, even though they have the same parents.  

Download unit guide

Illustration of a person in a red hat and fur-lined coat with eyes closed, surrounded by large orange circles on a dark background.
Thermal Energy

Domain: Physical Science

Unit type: Core

Student role: Thermal scientists

Phenomenon: One of two proposed heating systems for Riverdale School will best heat the school. 

Download unit guide

Abstract artwork depicting a bright sun with blue and orange swirling patterns next to green hills under a sky with shades of blue, orange, and red.
Ocean, Atmosphere, and Climate

Domains: Earth and Space Science, Physical Science

Unit type: Core

Student role: Climatologists

Phenomenon: During El Niño years, the air temperature in Christchurch, New Zealand is cooler than usual.  

An illustration from the Weather Patterns unit
Weather Patterns

Domains: Earth and Space Science, Physical Science

Unit type: Core

Student role: Forensic meteorologists

Phenomenon: In recent years, rainstorms in Galetown have been unusually severe.  

Download unit guide

An illustration from the Earth's Changing Climate unit
Earth’s Changing Climate

Domains: Earth and Space Science, Life Science

Unit type: Core

Student role: Climatologists

Phenomenon: The ice on Earth’s surface is melting.  

Download unit guide

Abstract geometric design in shades of blue and purple featuring a hexagon with icons of a building, wrench, molecules, sun, paint can, and screwdriver.
Earth’s Changing Climate Engineering Internship

Domains: Earth and Space Science, Engineering Design

Unit type: Engineering internship

Student role: Civil engineers

Phenomenon: Designing rooftops with different modifications can reduce a city’s impact on climate change.  

A barren, rocky desert landscape with rover tracks leading to a distant vehicle on a hill under a hazy sky.
Geology on Mars

Domain: Earth and Space Science

Unit type: Launch

Student role: Planetary geologists

Phenomenon: Analyzing data about landforms on Mars can provide evidence that Mars may have once been habitable. 

Two prehistoric reptiles with long snouts and tails are near the shore, one on land and one in water, with plants, rocks, and an island in the background.
Plate Motion

Domain: Earth and Space Science

Unit type: Core

Student role: Geologists

Phenomenon: Mesosaurus fossils have been found on continents separated by thousands of kilometers of ocean, even though the Mesosaurus species once lived all together.  

Download unit guide

Geometric design featuring a telescope, mountain, sound waves, and cosmic elements on a purple hexagonal background.
Plate Motion Engineering Internship

Domains: Earth and Space Science, Engineering Design

Unit type: Engineering internship

Student role: Mechanical engineering interns

Phenomenon: Patterns in earthquake data can be used to design an effective tsunami warning system.  

Illustration of a cross-section of Earth showing a volcano near the ocean. Trees, mountains, and clouds are visible above, with subterranean layers below.
Rock Transformations

Domain: Earth and Space Science

Unit type: Core

Student role: Geologists

Phenomenon: Rock samples from the Great Plains and from the Rocky Mountains — regions hundreds of miles apart — look very different, but have surprisingly similar mineral compositions.  

Download unit guide

Ilustración que muestra las etapas de fusión de una paleta de naranja: entera, parcialmente derretida, más derretida y casi derretida por completo, con palitos de madera, sobre un fondo morado.
Phase Change

Domains: Physical Science, Earth and Space Science

Unit type: Core

Student role: Chemists

Phenomenon: A methane lake on Titan no longer appears in images taken by a space probe two years apart

Download unit guide

Green geometric background with a hexagonal emblem containing a parachute icon, ruler, bandage, and stacked layers on a gradient pattern.
Force and Motion Engineering Internship

Domains: Engineering Design, Physical Science

Unit type: Engineering internship

Student role: Mechanical engineering interns

Phenomenon: Designing emergency supply delivery pods with different structures can maintain the integrity of the supply pods and their contents.  

An illustration from the Chemical Reactions unit
Chemical Reactions

Domains: Physical Science, Life Science, Earth and Space Science

Unit type: Core

Student role: Forensic chemists

Phenomenon: A mysterious brown substance has been detected in the tap water of Westfield.  

Download unit guide

An illustration of a whale with jellyfish and turtles from Amplify Science
Populations and Resources

Domains: Life Science, Earth and Space Science

Unit type: Core

Student role: Biologists

Phenomenon: The size of the moon jelly population in Glacier Sea has increased. 

Download unit guide

Low-poly landscape with trees and mushrooms. A fox sniffs the ground, a rabbit sits nearby, and mountains and sun are in the background.
Matter and Energy in Ecosystems

Domains: Life Science, Earth and Space Science, Physical Science

Unit type: Core

Student role: Ecologists

Phenomenon: The biodome ecosystem has collapsed.  

Download unit guide

Two people climbing rocky terrain; illustrations show a hiking boot and a belt with gear.
Harnessing Human Energy

Domains: Physical Science, Earth and Space Science, Engineering Design

Unit type: Launch

Student role: Energy scientists

Phenomenon: Rescue workers can use their own human kinetic energy to power the electrical devices they use during rescue missions.  

Illustration of a futuristic space station with large solar panels, orbiting in deep space, emitting a blue glow from its propulsion system.
Force and Motion

Domain: Physical Science

Unit type: Core

Student role: Physicists

Phenomenon: The asteroid sample-collecting pod failed to dock at the space station as planned.

Download unit guide

Green geometric graphic featuring icons: a baby, thermometer, layers, medical alert, and a flame.
Phase Change Engineering Internship

Domains: Engineering Design, Physical Science

Unit type: Engineering internship

Student role: Chemical engineering interns

Phenomenon: Designing portable baby incubators with different combinations of phase change materials can keep babies at a healthy temperature.  

Illustration of a roller coaster filled with people, hands raised, going down a steep track against a bright blue sky with clouds.
Magnetic Fields

Domain: Physical Science

Unit type: Core

Student role: Physicists

Phenomenon: During a test launch, a spacecraft traveled much faster than expected.  

An illustration from the Light Waves unit
Light Waves

Domains: Physical Science, Life Science, Earth and Space Science

Unit type: Core

Student role: Spectroscopists

Phenomenon: The rate of skin cancer is higher in Australia than in other parts of the world.

Download unit guide

A city skyline at night with a prominent full moon, stars in the sky, and a bridge silhouette on the left.
Earth, Moon, and Sun

Domains: Earth and Space Science, Physical Science

Unit type: Core

Student role: Astronomers

Phenomenon: An astrophotographer can only take pictures of specific features on the Moon at certain times.  

Download unit guide

Four low-poly dinosaurs with missing body sections are standing in a row; one is yellow, and the others are green. They have purple spikes and red patches on their bodies.
Natural Selection

Domains: Life Science, Earth and Space Science

Unit type: Core

Student role: Biologists

Phenomenon: The newt population in Oregon State Park has become more poisonous over time.  

Download unit guide

Red geometric background with icons including a mosquito, DNA strand, bar chart, and world map inside a hexagon.
Natural Selection Engineering Internship

Domains: Engineering Design, Life Science

Unit type: Engineering internship

Student role: Clinical engineers

Phenomenon: Designing malaria treatment plans that use different combinations of drugs can reduce drug resistance development while helping malaria patients.  

Two giant tortoises with long necks stand near water; one tortoise feeds on leaves from a tree while the other is near dense vegetation.
Evolutionary History

Domains: Life Science, Earth and Space Science

Unit type: Core

Student role: Paleontologists

Phenomenon: A mystery fossil at the Natural History Museum has similarities with both wolves and whales.    

Download unit guide

Resources

Two middle school girls use a Student Investigation Notebook to take on the role of scientists and engineers

Pilot support brochure for 6–8 (Integrated)

See how we customized our instructional sequence to fully support the Utah SEEd…

An illustration of a whale with jellyfish and turtles from Amplify Science

Unit phenomena for 6–8

Take a closer look at the unit phenomena featured in each grade level.

A laptop screen displays a simulation about Earth's energy system, with surrounding images showing diagrams and energy flow models.

Classroom Slides for 6–8

Your new hands-free TG is coming soon! These PowerPoints for every lesson make t…

A child wearing safety goggles closely examines an object through a magnifying glass in a classroom setting.

What’s so phenomenal about phenomena?

Learn actionable strategies that will help you implement 3-D teaching and learni…

A student reviews a science textbook and looks at a laptop in a classroom, while other students work together on their science projects in the background.

Active reading in 6–8

Learn how we support students in learning how to interact with scientific texts….

A young person wearing gloves looks through a microscope at a table with laboratory supplies, including bottles, slides, and a tray, against a plain blue background.

Investigations for 6–8

Explore the types of investigations that take place in middle school classrooms….

A laptop screen displaying a map with three ecosystem options, each illustrated by different animal icons and accompanied by relevant data lists.

Sims for 4–8

Two students sit at desks writing in notebooks and using laptops in a classroom setting.

Approaches to assessment in 6–8

Learn about our middle school embedded assessments.

A science education kit includes goggles, measuring cups, books on ecosystems and fuel burning, seeds, a jar, game pieces, and soil. Authored by The Lawrence Hall of Science.

Program component list for 6–8 (Integrated)

Explore the components that come with each unit.

A closer look at grades 6–8 (domain)

Amplify Science California is based on the latest research on teaching and learning and helps teachers deliver rigorous and riveting lessons through hands-on investigations, literacy-rich activities, and interactive digital tools that empower students to think, read, write, and argue like real scientists.

In the 6–8 classroom, this looks like students:

  • Collecting evidence from a variety of sources.
  • Making sense of evidence in a variety of ways.
  • Formulating convincing scientific arguments.

Is your school implementing the integrated model? Click here.

Collage of four images showing children engaged in educational activities such as conducting experiments and crafting in a classroom setting.
Graphic showing a research process with four steps: spark intrigue with a real-world problem, explore evidence, explain and elaborate, and evaluate claims, connected in a cycle with arrows.

Program structure

Our cyclical lesson design ensures students receive multiple exposures to concepts through a variety of modalities. As they progress through the lessons within a unit, students build and deepen their understanding, increasing their ability to develop and refine complex explanations of the unit’s phenomenon.

It’s this proven program structure and lesson design that enables Amplify Science California to teach less, but achieve more. Rather than asking teachers to wade through unnecessary content, we designed our 6–8 program to address 100% of the California NGSS in fewer lessons than other programs.

Scope and sequence

Every year of our grades 6–8 sequence consists of 9 units, with each unit containing 10–19 lessons. Lessons are written to last a minimum of 45 minutes, though teachers can expand or contract the timing to meet their needs.

A grid of educational icons, each representing a different science topic, such as earth and space science, life science, and physical science, with titles and lesson counts.

Unit types

Each unit delivers three-dimensional learning experiences and engages students in gathering evidence from a rich collection of sources, while also serving a unique purpose.

In grades 6–8, there are three types of units:

  • One unit is a launch unit.
  • Three units are core units.
  • Two units are engineering internships.
Launch units

Launch units are the first units taught in each year of Amplify Science California. The goal of the Launch unit is to introduce students to norms, routines, and practices that will be built on throughout the year, including argumentation, active reading, and using the program’s technology. For example, rather than taking the time to explain the process of active reading in every unit in a given year, it is explained thoroughly in the Launch unit, thereby preparing students to actively read in all subsequent units.

Core units

Core units establish the context of the unit by introducing students to a real-world problem. As students move through lessons in a Core unit, they figure out the unit’s anchoring phenomenon, gain an understanding of the unit’s disciplinary core ideas and science and engineering practices, and make linkages across topics through the crosscutting concepts. Each Core unit culminates with a Science Seminar and final writing activity.

Engineering Internship units

Engineering Internship units invite students to design solutions for real-world problems as interns for a fictional company called Futura. Students figure out how to help those in need, from tsunami victims in Sri Lanka to premature babies, through the application of engineering practices. In the process, they apply and deepen their learning from Core units.

Units at a glance

A barren, rocky desert landscape with rover tracks leading to a distant vehicle on a hill under a hazy sky.
Geology on Mars

Domain: Earth and Space Science

Unit type: Launch

Student role: Planetary geologists

Phenomenon: Analyzing data about landforms on Mars can provide evidence that Mars may have once been habitable.    

Two prehistoric reptiles with long snouts and tails are near the shore, one on land and one in water, with plants, rocks, and an island in the background.
Plate Motion

Domain: Earth and Space Science

Unit type: Core

Student role: Geologists

Phenomenon: Mesosaurus fossils have been found on continents separated by thousands of kilometers of ocean, even though the Mesosaurus species once lived all together.    

Download unit guide

Geometric design featuring a telescope, mountain, sound waves, and cosmic elements on a purple hexagonal background.
Plate Motion Engineering Internship

Domain: Earth and Space Science

Unit type: Engineering internship

Student role: Mechanical engineering interns

Phenomenon: Patterns in earthquake data can be used to design an effective tsunami warning system.    

Illustration of a cross-section of Earth showing a volcano near the ocean. Trees, mountains, and clouds are visible above, with subterranean layers below.
Rock Transformations

Domain: Earth and Space Science

Unit type: Core

Student role: Geologists

Phenomenon: Rock samples from the Great Plains and from the Rocky Mountains — regions hundreds of miles apart — look very different, but have surprisingly similar mineral compositions.    

Download unit guide

A city skyline at night with a prominent full moon, stars in the sky, and a bridge silhouette on the left.
Earth, Sun, and Moon

Domain: Earth and Space Science

Unit type: Core

Student role: Astronomers

Phenomenon: An astrophotographer can only take pictures of specific features on the Moon at certain times.    

Download unit guide

Abstract artwork depicting a bright sun with blue and orange swirling patterns next to green hills under a sky with shades of blue, orange, and red.
Ocean, Atmosphere, and Climate

Domain: Earth and Space Science

Unit type: Core

Student role: Climatologists

Phenomenon: During El Niño years, the air temperature in Christchurch, New Zealand is cooler than usual.    

Ilustración de un pueblo con casas, campos y montañas bajo un cielo nublado con olas de viento o lluvia.
Weather Patterns

Domain: Earth and Space Science

Unit type: Core

Student role: Forensic meteorologists

Phenomenon: In recent years, rainstorms in Galetown have been unusually severe.    

Download unit guide

Un oso polar se encuentra sobre un pequeño témpano de hielo en el océano con un sol naranja en el cielo y lejanas montañas heladas al fondo.
Earth’s Changing Climate

Domain: Earth and Space Science

Unit type: Core

Student role: Climatologists

Phenomenon: The ice on Earth’s surface is melting.    

Download unit guide

Abstract geometric design in shades of blue and purple featuring a hexagon with icons of a building, wrench, molecules, sun, paint can, and screwdriver.
Earth’s Changing Climate Engineering Internship

Domain: Earth and Space Science

Unit type: Engineering internship

Student role: Civil engineers

Phenomenon: Designing rooftops with different modifications can reduce a city’s impact on climate change.    

Abstract art with vibrant colors featuring a yellow silhouette of a person holding a book against a background of geometric shapes, swirling patterns, and bold textures.
Microbiome

Domain: Life Science

Unit type: Launch

Student role: Microbiological researchers

Phenomenon: The presence of 100 trillion microorganisms living on and in the human body may keep the body healthy.    

Abstract artwork of a person's side profile with geometric shapes and colorful patterns flowing from the head, holding a small sledgehammer. A vision chart is visible in the corner.
Metabolism

Domain: Life Science

Unit type: Core

Student role: Medical researchers

Phenomenon: Elisa, a young patient, feels tired all the time.    

Download unit guide

Orange abstract background with hexagonal shapes featuring icons of a bar chart, plant, safety vest, test tube, peach, and stethoscope.
Metabolism Engineering Internship

Domain: Life Science

Unit type: Engineering internship

Student role: Food engineers

Phenomenon: Designing health bars with different molecular compositions can effectively meet the metabolic needs of patients or rescue workers.    

Imagen que muestra un gráfico de arañas de diferentes colores con patrones distintos de patas y cuerpo, incluidas variaciones de color marrón, amarillo y azul. El fondo es una superficie oscura y texturizada.
Traits and Reproduction

Domain: Life Science

Unit type: Core

Student role: Biomedical students

Phenomenon: Darwin’s bark spider offspring have different silk flexibility traits, even though they have the same parents.    

Download unit guide

An illustration of a whale with jellyfish and turtles from Amplify Science
Populations and Resources

Domain: Life Science

Unit type: Core

Student role: Biologists

Phenomenon: The size of the moon jelly population in Glacier Sea has increased.    

Download unit guide

Low-poly landscape with trees and mushrooms. A fox sniffs the ground, a rabbit sits nearby, and mountains and sun are in the background.
Matter and Energy in Ecosystems

Domain: Life Science

Unit type: Core

Student role: Ecologists

Phenomenon: What caused the mysterious crash of a biodome ecosystem?    

Download unit guide

Four low-poly dinosaurs with missing body sections are standing in a row; one is yellow, and the others are green. They have purple spikes and red patches on their bodies.
Natural Selection

Domain: Life Science

Unit type: Core

Student role: Biologists

Phenomenon: The newt population in Oregon State Park has become more poisonous over time.    

Download unit guide

Red geometric background with icons including a mosquito, DNA strand, bar chart, and world map inside a hexagon.
Natural Selection Engineering Internship

Domain: Life Science

Unit type: Engineering internship

Student role: Clinical engineers

Phenomenon: Designing malaria treatment plans that use different combinations of drugs can reduce drug resistance development while helping malaria patients.  

Two giant tortoises with long necks stand near water; one tortoise feeds on leaves from a tree while the other is near dense vegetation.
Evolutionary History

Domain: Life Science

Unit type: Core

Student role: Paleontologists

Phenomenon: A mystery fossil at the Natural History Museum has similarities with both wolves and whales.    

Download unit guide

Two people climbing rocky terrain; illustrations show a hiking boot and a belt with gear.
Harnessing Human Energy

Domain: Physical Science

Unit type: Launch

Student role: Energy scientists

Phenomenon: Rescue workers can use their own human kinetic energy to power the electrical devices they use during rescue missions.    

Illustration of a futuristic space station with large solar panels, orbiting in deep space, emitting a blue glow from its propulsion system.
Force and Motion

Domain: Physical Science

Unit type: Core

Student role: Physicists

Phenomenon: The asteroid sample-collecting pod failed to dock at the space station as planned.    

Download unit guide

Green geometric background with a hexagonal emblem containing a parachute icon, ruler, bandage, and stacked layers on a gradient pattern.
Force and Motion Engineering Internship

Domain: Physical Science

Unit type: Engineering internship

Student role: Mechanical engineering interns

Phenomenon: Designing emergency supply delivery pods with different structures can maintain the integrity of the supply pods and their contents. 

Illustration of a roller coaster filled with people, hands raised, going down a steep track against a bright blue sky with clouds.
Magnetic Fields

Domain: Physical Science

Unit type: Core

Student role: Physicists

Phenomenon: During a test launch, a spacecraft traveled much faster than expected.    

Illustration of a person in a red hat and fur-lined coat with eyes closed, surrounded by large orange circles on a dark background.
Thermal Energy

Domain: Physical Science

Unit type: Core

Student role: Thermal scientists

Phenomenon: One of two proposed heating systems for Riverdale School will best heat the school.    

Download unit guide

Ilustración que muestra las etapas de fusión de una paleta de naranja: entera, parcialmente derretida, más derretida y casi derretida por completo, con palitos de madera, sobre un fondo morado.
Phase Change

Domain: Physical Science

Unit type: Core

Student role: Chemists

Phenomenon: A methane lake on Titan no longer appears in images taken by a space probe two years apart.    

Download unit guide

Green geometric graphic featuring icons: a baby, thermometer, layers, medical alert, and a flame.
Phase Change Engineering Internship

Domain: Physical Science

Unit type: Engineering internship

Student role: Chemical engineering interns

Phenomenon: Designing portable baby incubators with different combinations of phase change materials can keep babies at a healthy temperature.    

Obra de arte digital abstracta que presenta numerosos círculos rojos y grises superpuestos sobre un fondo dividido de azul y violeta claro, creando una composición dinámica y enérgica.
Chemical Reactions

Domain: Physical Science

Unit type: Core

Student role: Forensic chemists

Phenomenon: A mysterious brown substance has been detected in the tap water of Westfield.    

Download unit guide

An illustration from the Light Waves unit
Light Waves

Domain: Physical Science

Unit type: Core

Student role: Spectroscopists

Phenomenon: The rate of skin cancer is higher in Australia than in other parts of the world.    

Download unit guide

Resources

Pilot support brochure for 6–8 (Domain)

See how we customized our instructional sequence to fully support the Utah SEEd…

Unit phenomena for 6–8(Domain)

Take a closer look at the unit phenomena featured in each grade level.

What’s so phenomenal about phenomena?

Learn actionable strategies that will help you implement 3-D teaching and learni…

Un maestro se encuentra al frente de un salón de clases, explicando una lección que se muestra en una pantalla. Los estudiantes se sientan en sus escritorios y algunos levantan la mano.

Planning Guide for grades 6–8 (Domain)

Check out these tips for planning to teach.

Active reading in 6–8

Learn how we support students in learning how to interact with scientific texts….

Investigations for 6–8(Domain)

Explore the types of investigations that take place in middle school classrooms….

A laptop screen displaying a map with three ecosystem options, each illustrated by different animal icons and accompanied by relevant data lists.

Sims for 4–8

Take a closer look at the digital simulations included at each grade level.

Approaches to assessment in 6–8

Learn about our middle school embedded assessments.

A closer look at grades 6–8 (domain)

Amplify Science is based on the latest research on teaching and learning and helps teachers deliver rigorous and riveting lessons through hands-on investigations, literacy-rich activities, and interactive digital tools that empower students to think, read, write, and argue like real scientists.

In the 6–8 classroom, this looks like students:

  • Collecting evidence from a variety of sources.
  • Making sense of evidence in a variety of ways.
  • Formulating convincing scientific arguments.

Is your school implementing the domain model? Click here.

Collage of four images showing children engaged in educational activities such as conducting experiments and crafting in a classroom setting.
A four-step process: Spark intrigue, Explore evidence, Explain and elaborate, and Evaluate claims, leading to ongoing engagement and building complexity.

Program structure

Our cyclical lesson design ensures students receive multiple exposures to concepts through a variety of modalities. As they progress through the lessons within a unit, students build and deepen their understanding, increasing their ability to develop and refine complex explanations of the unit’s phenomenon.

It’s this proven program structure and lesson design that enables Amplify Science to teach less, but achieve more. Rather than asking teachers to wade through unnecessary content, we designed our 6–8 program to address 100% of the NGSS in fewer lessons than other programs.

Scope and sequence

Every year our grades 6–8 sequence consists of 9 units, with each unit containing 10–19 lessons. Lessons are written to last a minimum of 45-minutes, though teachers can expand or contract the timing to meet their needs.

A grid of educational icons, each representing a different science topic, such as earth and space science, life science, and physical science, with titles and lesson counts.

Unit types

Each unit delivers three-dimensional learning experiences and engages students in gathering evidence from a rich collection of sources, while also serving a unique purpose.

In grades 6–8, there are three types of units:

  • One unit is a launch unit.
  • Three units are core units.
  • Two units are engineering internships.
Launch units

Launch units are the first units taught in each year of Amplify Science. The goal of the Launch unit is to introduce students to norms, routines, and practices that will be built on throughout the year, including argumentation, active reading, and using the program’s technology. For example, rather than taking the time to explain the process of active reading in every unit in a given year, it is explained thoroughly in the Launch unit, thereby preparing students to actively read in all subsequent units.

Core units

Core units establish the context of the unit by introducing students to a real-world problem. As students move through lessons in a Core unit, they figure out the unit’s anchoring phenomenon, gain an understanding of the unit’s disciplinary core ideas and science and engineering practices, and make linkages across topics through the crosscutting concepts. Each Core unit culminates with a Science Seminar and final writing activity.

Engineering Internship units

Engineering Internship units invite students to design solutions for real-world problems as interns for a fictional company called Futura. Students figure out how to help those in need, from tsunami victims in Sri Lanka to premature babies, through the application of engineering practices. In the process, they apply and deepen their learning from Core units.

Units at a glance

A rover sits on a rocky, reddish hill under a hazy sky, leaving visible tire tracks across the barren landscape.
Geology on Mars

Domain: Earth and Space Science

Unit type: Launch

Student role: Planetary geologists

Phenomenon: Analyzing data about landforms on Mars can provide evidence that Mars may have once been habitable.    

Two prehistoric marine reptiles with long snouts are near a rocky shoreline, one on land and one in the water, with an island and clouds in the background.
Plate Motion

Domain: Earth and Space Science

Unit type: Core

Student role: Geologists

Phenomenon: Mesosaurus fossils have been found on continents separated by thousands of kilometers of ocean, even though the Mesosaurus species once lived all together.    

A geometric badge with a mountain, telescope, and audio wave icons on a purple background with polygonal shapes.
Plate Motion Engineering Internship

Domain: Earth and Space Science

Unit type: Engineering internship

Student role: Mechanical engineering interns

Phenomenon: Patterns in earthquake data can be used to design an effective tsunami warning system.    

Illustration of a volcano by the sea with smoke, trees, mountains, and a cross-section showing a fault line beneath the ground.
Rock Transformations

Domain: Earth and Space Science

Unit type: Core

Student role: Geologists

Phenomenon: Rock samples from the Great Plains and from the Rocky Mountains — regions hundreds of miles apart — look very different, but have surprisingly similar mineral compositions.    

Illustration of a city skyline at night with buildings, a bridge, and a large full moon in a starry sky.
Earth, Sun, and Moon

Domain: Earth and Space Science

Unit type: Core

Student role: Astronomers

Phenomenon: An astrophotographer can only take pictures of specific features on the Moon at certain times.    

Abstract digital painting of a landscape with green hills, a red-orange horizon, and a large yellow sun surrounded by blue and orange swirling shapes on the right.
Ocean, Atmosphere, and Climate

Domain: Earth and Space Science

Unit type: Core

Student role: Climatologists

Phenomenon: During El Niño years, the air temperature in Christchurch, New Zealand is cooler than usual.    

Illustration of a town with houses and fields under a sky with large clouds and swirling wind patterns, set against a backdrop of hills and mountains.
Weather Patterns

Domain: Earth and Space Science

Unit type: Core

Student role: Forensic meteorologists

Phenomenon: In recent years, rainstorms in Galetown have been unusually severe.    

A polar bear stands on a small ice floe surrounded by water and floating ice under a red sun in an Arctic landscape.
Earth’s Changing Climate

Domain: Earth and Space Science

Unit type: Core

Student role: Climatologists

Phenomenon: The ice on Earth’s surface is melting.    

Hexagonal badge with icons including a wrench, building, sun, screwdriver, paint can, and molecules on a purple geometric background.
Earth’s Changing Climate Engineering Internship

Domain: Earth and Space Science

Unit type: Engineering internship

Student role: Civil engineers

Phenomenon: Designing rooftops with different modifications can reduce a city’s impact on climate change.    

Colorful abstract digital artwork featuring a yellow figure holding a device, with blue and red shapes and textured patterns in the background.
Microbiome

Domain: Life Science

Unit type: Launch

Student role: Microbiological researchers

Phenomenon: The presence of 100 trillion microorganisms living on and in the human body may keep the body healthy.    

An abstract illustration of a person having their mouth and throat examined with a tongue depressor, surrounded by colorful shapes, with an eye chart in the background.
Metabolism

Domain: Life Science

Unit type: Core

Student role: Medical researchers

Phenomenon: Elisa, a young patient, feels tired all the time.    

Geometric orange background with a hexagon icon displaying symbols for statistics, farming, healthcare, safety vest, chemistry, and agriculture.
Metabolism Engineering Internship

Domain: Life Science

Unit type: Engineering internship

Student role: Food engineers

Phenomenon: Designing health bars with different molecular compositions can effectively meet the metabolic needs of patients or rescue workers.    

Six spiders with different colors and stripe patterns are arranged in a grid pattern on a dark background, showing variations in leg and body color.
Traits and Reproduction

Domain: Life Science

Unit type: Core

Student role: Biomedical students

Phenomenon: Darwin’s bark spider offspring have different silk flexibility traits, even though they have the same parents.    

An underwater scene shows a whale surrounded by jellyfish, sea turtles, and fish, with sunlight filtering through the water.
Populations and Resources

Domain: Life Science

Unit type: Core

Student role: Biologists

Phenomenon: The size of the moon jelly population in Glacier Sea has increased.    

A low-poly landscape with trees, mushrooms, a rabbit sitting, and a fox bending down near another rabbit under a sunny sky with mountains in the background.
Matter and Energy in Ecosystems

Domain: Life Science

Unit type: Core

Student role: Ecologists

Phenomenon: What caused the mysterious crash of a biodome ecosystem?    

Three green dinosaurs and one yellow dinosaur stand in a row on grass, each with purple spikes and a red spot on their backs. The sky is blue with light clouds.
Natural Selection

Domain: Life Science

Unit type: Core

Student role: Biologists

Phenomenon: The newt population in Oregon State Park has become more poisonous over time.    

Red-toned graphic with hexagonal badge featuring a world map, a mosquito, a DNA strand, charts, cubes, and circular icons. Geometric background pattern.
Natural Selection Engineering Internship

Domain: Life Science

Unit type: Engineering internship

Student role: Clinical engineers

Phenomenon: Designing malaria treatment plans that use different combinations of drugs can reduce drug resistance development while helping malaria patients.  

Two giant tortoises are near a river; one is by the water and the other is standing on land and stretching its neck toward a leafy tree.

Evolutionary History

Domain: Life Science

Unit type: Core

Student role: Paleontologists

Phenomenon: A mystery fossil at the Natural History Museum has similarities with both wolves and whales.    

Two people climb over rocky terrain strewn with electronic waste, with illustrated insets showing a hiking boot, a solar-powered device, and a person adjusting a belt-like gadget.
Harnessing Human Energy

Domain: Physical Science

Unit type: Launch

Student role: Energy scientists

Phenomenon: Rescue workers can use their own human kinetic energy to power the electrical devices they use during rescue missions.    

A spacecraft approaches a modular space station with large solar panels, set against a backdrop of outer space.
Force and Motion

Domain: Physical Science

Unit type: Core

Student role: Physicists

Phenomenon: The asteroid sample-collecting pod failed to dock at the space station as planned.    

Green geometric background with a hexagonal badge showing a parachute, a box, a ruler, a bandage, and stacked layers.
Force and Motion Engineering Internship

Domain: Physical Science

Unit type: Engineering internship

Student role: Mechanical engineering interns

Phenomenon: Designing emergency supply delivery pods with different structures can maintain the integrity of the supply pods and their contents. 

Illustration of a roller coaster car full of people with raised arms, speeding down a loop against a blue sky with clouds.
Magnetic Fields

Domain: Physical Science

Unit type: Core

Student role: Physicists

Phenomenon: During a test launch, a spacecraft traveled much faster than expected.    

Illustration of a person in a red coat and hat with arms crossed, eyes closed, surrounded by large orange and brown circles, possibly representing snow or lights.
Thermal Energy

Domain: Physical Science

Unit type: Core

Student role: Thermal scientists

Phenomenon: One of two proposed heating systems for Riverdale School will best heat the school.    

An orange popsicle gradually melts, shown in four stages from solid to completely melted, with wooden sticks visible, against a purple background.
Phase Change

Domain: Physical Science

Unit type: Core

Student role: Chemists

Phenomenon: A methane lake on Titan no longer appears in images taken by a space probe two years apart.    

A green background with a picture of a person and a sandwich.
Phase Change Engineering Internship

Domain: Physical Science

Unit type: Engineering internship

Student role: Chemical engineering interns

Phenomenon: Designing portable baby incubators with different combinations of phase change materials can keep babies at a healthy temperature.    

Digital illustration showing red and blue molecules on a blue background transitioning to a lighter background, representing molecular diffusion across a boundary.
Chemical Reactions

Domain: Physical Science

Unit type: Core

Student role: Forensic chemists

Phenomenon: A mysterious brown substance has been detected in the tap water of Westfield.    

Illustration of Earth with yellow arrows and colored waves approaching from the left, representing incoming solar or cosmic radiation.
Light Waves

Domain: Physical Science

Unit type: Core

Student role: Spectroscopists

Phenomenon: The rate of skin cancer is higher in Australia than in other parts of the world.    

Resources

Pilot support brochure for grades 6–8 (Domain…

Unit phenomena for grade 6-8 (Domain)

Take a closer look at the unit phenomena featured in each grade level.

Classroom Slides for 6–8

Your new hands-free TG is coming soon! These PowerPoints for every lesson make t…

What’s so phenomenal about phenomena?

Learn actionable strategies that will help you implement 3-D teaching and learni…

Planning Guide for grades 6–8 (Domain)

Check out these tips for planning to teach.

Active reading in grades 6–8

Scientists read and write with purpose too.

Investigations for grades 6–8 (Domain)

Explore the types of investigations that take place in 6–8 classrooms.

A laptop screen displaying a map with three ecosystem options, each illustrated by different animal icons and accompanied by relevant data lists.

Sims for grades 4–8

Take a closer look at the digital simulations included at each grade level.

Approaches to assessment at 6–8

Learn about our embedded assessments.

Welcome, Utah K-8 reviewers!

To view this protected page, enter the password below:



A continuous line drawing of three people sitting at a table, appearing to look at or discuss something on the tabletop.

Careers

We’re looking for innovators and optimists to join us in developing next-generation curriculum and assessment programs for K–12 schools.

View open positions

Who we are

Remote first. Brooklyn based. In person sometimes. Amplify is powered by a collaborative team of education, technology, and creative professionals who develop next-generation programs that inspire teachers and students to do their best work.  Apply for one of our open positions.

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People and culture

Amplify is a purpose-driven community where cross-functional teams work together to create high-quality programs.

Share our view.

With headquarters in Brooklyn’s DUMBO neighborhood, we’re at the center of New York’s thriving tech and creative community.

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Two men stand in an office, one in a blue shirt and the other in a red-checked shirt, looking at computer monitors and appearing engaged in conversation.

Get inspired.

We take an agile approach that enables us to adapt our programs to the needs of teachers and students. Collaboration helps us stay innovative.

Meet the team.

Our common purpose drives us to work across disciplines to develop next-generation solutions for the classroom. Meet some of our team members.

Meet the team
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Three people smiling, each in a circular frame on a light grey background.

Leadership

Amplify’s leadership includes executives and board members from the fields of education, technology, design, business, and media.

Our team

Hiring practices

We hire and develop people with the broadest range of talents, life stories, and experiences, and together we build a cohesive team. We follow fair hiring practices and create an environment where team members feel valued, empowered, and heard.

A man in a yellow shirt works on a laptop at a desk in an office with other people in the background.

Amplify workplace awards

Three people collaborate at a laptop. Text on image reads "Built In: The Best Places to Work, 2024 Winning Workplace!.

Best fully remote places to work

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The most transformational growth co…

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Excellence in back to school 2023

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What we offer

Amplify employees report feeling engaged and eager to come to work every day. They’re motivated by our mission of improving the lives of teachers and students. And learning isn’t just for the students we serve—we are dedicated to providing our employees opportunities for ongoing growth. Explore our benefits in detail.

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Full benefits

Our health insurance options include health, dental, and vision coverage for spouses, domestic partners, and children—effective on your date of hire. We make a generous contribution to all employee HSA plans, which can be used to cover eligible health expenses. We offer unlimited paid time off, a 401(k) plan with an employer match, long- and short-term disability, and employer-sponsored employee life insurance. We offer paid parental leave, backup childcare and backup eldercare. On top of all that, we also provide our full-time employees with a robust voluntary benefits program that includes coverage options for everyone in the family, including pets.

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Opportunities for inspiration

Amplify believes in the importance of supporting charitable nonprofits in the communities where we live and work. We encourage employees to support organizations that promote the welfare of children and families in the areas of education, health, and social services. One way for employees to give back is through our Volunteer Time Off program, which allows employees to take 16 hours each year to contribute to an eligible charitable or nonprofit organization.

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Tuition reimbursement

Full-time employees who are enrolled in an accredited college or university course related to their areas of work are eligible to receive tuition reimbursement.

We’re hiring.

Want to use your talents to make a real difference—and have fun doing it? Come join us.

View open positions