Erosion is a natural hazard that causes major damage and can cause homes to collapse. In this storyline, students are introduced to weathering and erosion. Students will gain an understanding of coastal erosion by experimenting with different types of erosion control practices, including seawalls and riprap.

While food waste is not typically seen as contributing to greenhouse gas emissions, it is a major contributor. Reducing food waste ranks as the 3rd most beneficial drawdown solution. Wasted food, and the resources to produce that food, are responsible for approximately 8% of global greenhouse gas emissions. When individuals and groups reduce food waste, it has a huge impact on reducing greenhouse gas emissions. Food waste awareness is applicable to every person and community. In this storyline, students connect with cultural values around food, impacts of food waste and solutions to food waste issues.  

Mientras que el desperdicio de comida no es típicamente visto como un contribuyente de emisiones de gas de efecto invernadero, es un contribuyente mayor, siendo la 3ʳᵃ solución más beneficiosa. La comida desperdiciada y los recursos para producirla, son responsables del aproximadamente 8% de las emisiones globales de gases de efecto invernadero. Cuando los individuos y grupos reducen el desperdicio de comida, esto tiene un gran impacto en la reducción de emisiones de gases de efecto invernadero. La conciencia del desperdicio de comida se aplica a cada persona y comunidad. En este caso, los estudiantes se conectan con valores culturales alrededor de la comida, los impactos del desperdicio de comida y las soluciones a los problemas de desperdicio de comida.

PhD Science Grade Levels K–2 is available as downloadable PDFs. The OER consists of Teacher Editions and student Science Logbooks for every module.

With PhD Science®, students explore science concepts through authentic phenomena and events—not fabricated versions—so students build concrete knowledge and solve real-world problems. Students drive the learning by asking questions, gathering evidence, developing models, and constructing explanations to demonstrate the new knowledge they’ve acquired. The coherent design of the curriculum across lessons, modules, and grade levels helps students use the concepts they’ve learned to build a deep understanding of science and set a firm foundation they’ll build on for years to come.

Cross-curricular connections are a core component within PhD Science. As an example, every module incorporates authentic texts and fine art to build knowledge and create additional accessible entry points to the topic of study.

Three-dimensional teaching and learning are at the heart of the curriculum. As students uncover Disciplinary Core Ideas by engaging in Science and Engineering Practices and applying the lens of Cross-Cutting Concepts, they move from reading about science to doing science.

Great Minds® is the creator of Eureka Math®, Wit & Wisdom®, Alexandria Plan™, and PhD Science®.
Published by Great Minds PBC. greatminds.org
Copyright © 2021 Great Minds PBC. Except where otherwise noted, this PK-2 PhD Science® content is published under Great Minds OER License #1. Use limited to Non-Commercial educational purposes.
COMMERCIAL REPRODUCTION PROHIBITED.

See OER license details here:
https://s3.greatminds.org/link_files/files/000/003/991/original/Final_Form_OER_PhD_Science_K-2_limited_public_license_%282.10.21%29.pdf

Throughout the module, students study the anchor phenomenon, the cliff dwellings at Mesa Verde, and build an answer to the Essential Question: How did the cliff dwellings at Mesa Verde protect people from the weather? As students learn about each new concept, they develop and refine a model that represents a cliff dwelling and use that model to explore how cliff dwellings protected people from the weather. At the end of the module, students use their knowledge of weather to explain the anchor phenomenon, and they apply their learning to a new context in an End-of-Module Assessment. Through these experiences, students begin to establish an enduring understanding of weather and its effects. Specifically, students develop an understanding of the parts of weather, the effects weather has on people and their surroundings, and the ways people prepare for severe weather.

With PhD Science®, students explore science concepts through authentic phenomena and events—not fabricated versions—so students build concrete knowledge and solve real-world problems. Students drive the learning by asking questions, gathering evidence, developing models, and constructing explanations to demonstrate the new knowledge they’ve acquired. The coherent design of the curriculum across lessons, modules, and grade levels helps students use the concepts they’ve learned to build a deep understanding of science and set a firm foundation they’ll build on for years to come.

Cross-curricular connections are a core component within PhD Science. As an example, every module incorporates authentic texts and fine art to build knowledge and create additional accessible entry points to the topic of study.

Three-dimensional teaching and learning are at the heart of the curriculum. As students uncover Disciplinary Core Ideas by engaging in Science and Engineering Practices and applying the lens of Cross-Cutting Concepts, they move from reading about science to doing science.

© 2020–2022 Great Minds PBC. Except where otherwise noted, this content is published under Great Minds OER License 1 (greatminds.org/gm_oer_1). Use limited to noncommercial educational purposes. COMMERCIAL REPRODUCTION PROHIBITED.

In this hands-on inquiry-based activity, students face an engineering challenge based on real-world applications. They are tasked with developing a tool they can use to measure the amount of rain that falls each day. This is more of a mini unit than a stand alone activity.

Warming oceans and melting landlocked ice caused by global climate change may result in rising sea levels. This rise in sea level combined with increased intensity and frequency of storms will produce storm surges that flood subways, highways, homes, and more. In this activity, visitors design and test adaptations to prepare for flooding caused by sea level rise.

This unit consists of five lessons covering architecture and structural engineering. Each lesson includes goals, anticipatory set, learner objectives, guided practice, procedure instructions, closing activities, and extensions. Student handouts and worksheets are also included.

Lesson 1: Animal Structures
Lesson 2: Homes
Lesson 3: Stability
Lesson 4: Local Towers & Bridges
Lesson 5: Schools

NGSS: K-2-ETS1-1, K-2-ETS1-2, K-2-ETS1-3, 3-5-ETS1-1, 3-5-ETS1-2, 3-5-ETS1-3

Materials: blocks or other building toys, ruler, book or ball (for weight), graph paper, pencils, and floor plan of school or hand-drawn approximation featuring highlights.

This unit consists of five lessons encouraging younger learners to engineer increasingly better towers using blocks and recycled materials. Each 30 minute lesson ("phase") includes goals, discussion, activity instructions, extensions, and student worksheets.

Phase 1: Paper Cut-Outs Activity
Phase 2: Building Blocks Activity
Phase 3: Number of Blocks Activity
Phase 4: Building within a Space Activity
Phase 5: Recycled Tower Activity

NGSS: K-2-ETS1-1, K-2-ETS1-2, K-2-ETS1-3

Common Core ELA: RI.2.1, W.2.6, W.2.8, SL.2.5

Common Core Math: MP.2, MP.4, MP.5, 2.MD.D.10

Incorporating your schoolyard into your classroom can be a powerful tool for making learning meaningful and engaging for your students. Local and relevant phenomena can engage your student’s prior understandings, better connect to their interests and identities, and help in draw in students who don’t see science, reading or writing connecting to their lives.  This online course is a series of professional development workshops for Early Elementary (K-2) educators, developed by IslandWood with funding from the OSPI ClimeTime Grant. A slide deck and accompanying handouts supplement the course outline for a complete picture. 

This is a STEAM lesson designed for first or second grade students who are learning about the water cycle. 

In this activity, students discuss the notion of time and how time can be measured. They build an hourglass to measure time and test it. This activity will allow students to have a better understanding of time and the instruments that can be used to measure it.