Students pretend they are agricultural engineers during the colonial period and design a miniature plow that cuts through a "field" of soil. They are introduced to the engineering design process and learn of several famous historical figures who contributed to plow design.

Students use their creative skills to determine a way to safely mail raw (dry, uncooked) spaghetti using only the provided materials. To test the packing designs, the spaghetti is mailed through the postal system and evaluated after delivery.

This is a highly adaptable outline for how design thinking could be introduced to your learners over a multi-day project. This plan works best if students are divided up into groups of 3-4 for all work except the introduction to each concept at the beginning of class. Learners should stay in the same group for the whole class.

Includes pre-work links, general instructions to guide planning for each day, design thinking student handouts, and multi-grade NGSS standards linked to design thinking.

In this lesson, students will embark on a journey of discovery by researching a specific biome of their choice, such as rainforests, deserts, or coral reefs. They will delve into the unique characteristics, flora, and fauna that define their chosen biome, gaining insights into its environmental challenges and adaptations. Using Tinkercad, students will then design and create a miniature 3D model representing their biome, incorporating elements like plants, animals, and geographical features. Through this hands-on activity, students will not only enhance their digital design skills but also deepen their understanding of ecosystems, biodiversity, and the delicate balance within different biomes. This lesson fosters creativity, scientific inquiry, and a holistic appreciation of the natural world in STEM education. 

The purpose of this activity is for the students to draw a design for their own flying machine. They will apply their knowledge of aircraft design and the forces acting on them. The students will start with a brainstorming activity where they come up with creative uses for every day objects. They will then use their creativity and knowledge of airplanes to design their own flying machine.

Students create a concept design of their very own net-zero energy classroom by pasting renewable energy and energy-efficiency items into and around a pretend classroom on a sheet of paper. They learn how these items (such as solar panels, efficient lights, computers, energy meters, etc.) interact to create a learning environment that produces as much energy as it uses.

Students are tasked with designing a room of their choice in TinkerCAD. After learning the basic tools and navigation from modeling objects, they can begin to model collections of objects enabling them to visualize and personalize their dream spaces. Experimenting with layout, furniture, and décor helps develop their spatial awareness and design skills. The lesson concludes with an (optional) presentation, where participants present their room designs and reflect on their creative decisions and practical layouts. 

In this TinkerCAD lesson, students design their favorite toy using 3D modeling software. They learn basic TinkerCAD tools and techniques to create and customize their toy designs. Throughout the lesson, students apply principles of geometry and spatial reasoning while fostering creativity and problem-solving skills. The session concludes with students presenting their designs and discussing the features and functionality of their creations.

Students learn how to use wind energy to combat gravity and create lift by creating their own tetrahedral kites capable of flying. They explore different tetrahedron kite designs, learning that the geometry of the tetrahedron shape lends itself well to kites and wings because of its advantageous strength-to-weight ratio. Then they design their own kites using drinking straws, string, lightweight paper/plastic and glue/tape. Student teams experience the full engineering design cycle as if they are aeronautical engineers—they determine the project constraints, research the problem, brainstorm ideas, select a promising design and build a prototype; then they test and redesign to achieve a successful flying kite. Pre/post quizzes and a worksheet are provided.

Student teams act as engineers and brainstorm, design, create and test their ideas for packaging to protect a raw egg shipped in a 9 x 12-in envelope. They follow the steps of the engineering design process and aim for a successful solution with no breakage, low weight, minimal materials and recyled/reused materials. Students come to understand the multi-faceted engineering considerations associated with the packaging of items to preserve, market and safely transport goods.

Design challenge: Strong, light structures are necessary in constructing buildings (especially in areas with extreme weather) as well as air and space craft.

In this activity, students investigate different methods (aeration and filtering) for removing pollutants from water. They will design and build their own water filters.

This lesson is about the solar system and its objects, such as planets, moons, asteroids, and comets, it is revolving around the place where each celestial body resides. It engages students in exploring, researching, modeling, and discussing these objects and their characteristics, as well as the factors that make Earth habitable and the importance of space exploration. The lesson has four main parts: an introduction, where students are hooked by a hidden moon rock and learn about the lesson’s objectives and agenda; an exploration, where students work in groups to research various solar system objects using classroom resources and the NASA Solar System Exploration website, formulating questions about the solar system; an activity, where groups create models to represent Earth under different solar system conditions, based on “what if” questions, and present their findings; and a discussion, where a class discussion follows, focusing on the habitability factors of planets and the importance of space exploration. The lesson ends with students writing and peer-reviewing reflections on what they have learned.

Students learn about the amazing adaptations of the ptarmigan to the alpine tundra. They focus one adaptation, the feathered feet of the ptarmigan, and ask whether the feathers serve to only keep the feet warm or to also provide the bird with floatation capability. They create model ptarmigan feet, with and without feathers, and test the hypothesis on the function of the feathers. Ultimately, students make a claim about whether the feathers provide floatation and support this claim with their testing evidence.

The "Double-O-STEM" (educator guide) curriculum consists of STEM problem-solving activities. The curriculum is designed around projects that empower learners to apply STEM to creatively problem-solve community issues. These include designing bike lanes, community gardens, and other exciting STEM problems.

The activities are designed for both librarians and STEM educators. The curriculum is especially aligned with the Next Generation Science Standards (NGSS (engineering; grades 3-5) and American Association of School Librarians (AASL) standards.

Please note the student version can be found using the following link:
https://www.oercommons.org/courses/double-o-stem-learner-guide

The "Double-O-STEM" (learner guide) curriculum consists of STEM problem-solving activities. The curriculum is designed around projects that empower learners to apply STEM to creatively problem-solve community issues. These include designing bike lanes, community gardens, and other exciting STEM problems.

The activities are designed for both librarians and STEM educators. The curriculum is especially aligned with the Next Generation Science Standards (NGSS (engineering; grades 3-5) and American Association of School Librarians (AASL) standards.

Please note the educator guide can be found using the following link: https://www.oercommons.org/courses/double-o-stem-educator-guide

In this virtual professional development opportunity designed for teachers, EarthGen explores two global crises taking place concurrently - the climate crisis and COVID-19. What are the connections between the two? Why are BIPOC (Black, Indigenous, People of Color) communities disproportionately affected by both? Educators receive foundational information around climate justice, analyze the variables associated with vulnerability, exposure, and risk, and explore educational resources to bring this content into their classrooms.Contact EarthGen at info@earthgenwa.org for more information.

In this virtual professional development opportunity designed for teachers, participants will have a chance to authentically engage with activities and experts as they grow their understanding of how climate change has and will impact their community. Teachers analyze and interpret recent climate science data and progress understanding on the most salient climate change indicators in Washington. Additionally, teachers explore the efforts to conserve and protect a local species, its cultural significance and how these efforts are indicative of a greater effort to address climate change. Teachers leave this training with increased preparedness to leverage a local species or climate change impact in their classroom to spur action in their community. Contact EarthGen at info@earthgenwa.org for more information.

This task, by ClimeTime educators, is for 4th grade students. After class brainstorm of the causes and effects of flooding on a playground or in a local context, students will generate solutions to the problems related to the flooding. Students will select two solutions to describe how the solutions could be implemented and what factors affect the success of the solutions. Students will describe which of the two solutions they think is best and the reasons for their decision.
The resource includes a student task document, teacher guide, and task facilitation slides.