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.

Student teams design and create LEGO® structures to house and protect temperature sensors. They leave their structures in undisturbed locations for a week, and regularly check and chart the temperatures. This activity engages students in the design and analysis aspects of engineering.

In this interactive lesson plan, students collaborate to design a Mars base, applying concepts in engineering, architecture, and sustainability. Working in teams, they creatively solve challenges related to life support, resource management, and adapting to Martian conditions. Students draw out detailed floor plans for their innovative designs, showcasing their understanding of STEM principles and presenting their vision for a functional Martian habitat.

Students brainstorm ideas for board game formats. Then student teams design, create and test games in which players must think of alternative uses (recycling) for used products.

Students design and build a model city powered by the sun! They learn about the benefits of solar power, and how architectural and building engineers integrate photovoltaic panels into the design of buildings.

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.

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.

In this activity, students squeeze a tennis ball to demonstrate the strength of the human heart. Working in teams, they think of ways to keep the heart beating if the natural mechanism were to fail. The goal of this activity is to get students to understand the strength and resilience of the heart.

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

Students learn how engineers construct buildings to withstand damage from earthquakes by building their own structures with toothpicks and marshmallows. Students test how earthquake-proof their buildings are by testing them on an earthquake simulated in a pan of Jell-O(TM).

Explore WWII and Astronaut survival kits, what they contained and culminates with students designing an emergency preparedness kit.

This parent guide supports the creation of an emergency preparedness kit for home along with how to create an entire emergency plan.

During this lesson, students will learn about emergency preparedness during World War I and the Apollo mission, equipping them to participate in a challenge to design their own kit.

Students build small-sized prototypes of mountain rescue litters rescue baskets for use in hard-to-get-to places, such as mountainous terrain to evacuate an injured person (modeled by a potato) from the backcountry. Groups design their litters within constraints: they must be stable, lightweight, low-cost, portable and quick to assemble. Students demonstrate their designs in a timed test during which they assemble the litter and transport the rescued person (potato) over a set distance.

This unit covers the broad spectrum of topics that make-up our very amazing human body. Students are introduced to the space environment and learn the major differences between the environment on Earth and that of outer space. The engineering challenges that arise because of these discrepancies are also discussed. Then, students dive into the different components that make up the human body: muscles, bones and joints, the digestive and circulatory systems, the nervous and endocrine systems, the urinary system, the respiratory system, and finally the immune system. Students learn about the different types of muscles in the human body and the effects of microgravity on muscles. Also, they learn about the skeleton, the number of and types of bones in the body, and how outer space affects astronauts' bones. In the lessons on the digestive, circulatory, nervous and endocrine systems, students learn how these vital system work and the challenges faced by astronauts whose systems are impacted by spaceflight. And lastly, advances in engineering technology are discussed through the lessons on the urinary, respiratory and immune systems while students learn how these systems work with all the other body components to help keep the human body healthy.

The purpose of this activity is to demonstrate the importance of rocks, soils and minerals in engineering and how using the right material for the right job is important. The students build three different sand castles and test them for strength and resistance to weathering. Then, they discuss how the buildings are different and what engineers need to think about when using rocks, soils and minerals for construction.

Students begin by reading Dr. Seuss' "The Lorax" as an example of how overdevelopment can cause long-lasting environmental destruction. Students discuss how to balance the needs of the environment with the needs of human industry. Student teams are asked to serve as natural resource engineers, city planning engineers and civil engineers with the task to replant the nearly destroyed forest and develop a sustainable community design that can co-exist with the re-established natural area.