The ocean's resources are slowly being depleted. This curriculum examines the issue of overfishing and its impact on both the environment and human life. In developing sustainable solutions, the students address the driving question: "How can we as youth, sustain the future of the world's ocean through our actions today?"

The Wasted: Don't Trash the Earth curriculum asks students to examine the impact of the waste we locally and globally produce and seek creative solutions to reduce this wastefulness by answering the driving question: "How can we, as youth, rethink waste?"

This is a debate-style learning activity in which student teams learn about energy sources and are then assigned to represent the different energy sources. Working cooperatively, students develop arguments on the pros and cons of their source over the others.

In this role-play activity, students take the roles of various important players in the climate change policy negotiation including politicians, scientists, environmentalists, and industry representatives. Working in these roles, students must take a position, debate with others, and then vote on legislation designed to reduce greenhouse gas emissions in the United States. Can be used in a variety of courses including writing and rhetoric, and social sciences.

How can we manufacture environmentally friendly fuels using renewable sources? In this lesson, students will explore the process used to produce biodiesel from soybeans and test the efficiency of their fuel. 

The High School Integrated Conceptual Science Program (ICSP) is a NGSS-aligned curriculum that utilizes the conceptual progressions model for bundling of the NGSS, High School Conceptual Model Course 1 and strategies from Ambitious Science Teaching (AST) to focus on teaching practices needed to engage students in science discourse and learning. Course 1 is the High School Integrated Physics and Chemsitry Course.   The goal of these units is to encourage students to continue in STEM by providing engaging and aligned curriculum. The focus of this year long course is on the first year of high school (freshman).  While the course is designed to be taught as a collection of the units, each unit could be taught as a separate unit in a science course.  A video about the new course shared its unique approach to learning and teaching. Wenatchee School District, one of the participating districts, wanted a way to share the program with the community. https://youtu.be/9AGk19YUi2oCourse 1 of the ICSP development was funded by Northwest Earth and Space Sciences Pipeline (NESSP) which is funded through the NASA Science Mission Directorate and housed with Washington NASA Space Grant Consortium at the University of Washington.

Students apply their mathematics and team building skills to explore the concept of rocketry. They learn about design issues faced by aerospace engineers when trying to launch rocketships or satellites in order to land them safely in the ocean, for example. Students learn the value of designing within constraints while brainstorming a rocketry system using provided materials and a specified project budget. Throughout the design process, teamwork is emphasized since the most successful launches occur when groups work effectively to generate creative ideas and solutions to the rocket challenge.

This animation illustrates how heat energy from deep in Earth can be utilized to generate electricity at a large scale.

Students learn how roadways are designed and constructed, and discuss the advantages and limitations of the current roadway construction process. They look at current practices of roadway monitoring, discuss the limitations, and consider ways to further road monitoring research. To conclude, student groups compete to design smooth, cost-efficient and sound model road bases using gravel, sand, water and rubber (representing asphalt). This lesson prepares students for the associated activity in which they act as civil engineers hired by USDOT to research through their own model experimentation how to best use piezoelectric materials to detect road damage by showing how piezoelectric transducers can indicate road damage.

Learn how to make a water filter using materials from around your home or classroom.

Students redesign and justify the packaging used in consumer products. Design criteria include reducing the amount of packaging material by 25%.

Working with HTML canvas element with JavaScript to reduce the color noise to an acceptable range for monochrome prepared for edge detection between 27color range

The Integrated Conceptual Science Program Course 1 Integrated Physics and Chemistry is a three dimensional course based on the Conceptual Progression Model of the Next Generation Science Standards. It is designed to be used as part of a three course program that addresses all high school science performance expectations. Course 1 is designed for ninth grade students.
This resource includes the teacher materials, supporting documents, and short videos to support teachers in using the materials.
The Courses were designed using the Ambitious Science Teaching (AST) framework. It is strongly encouraged that before using these materials that you be familiar with AST. We suggest that you watch the AST Overview short video found here: https://datapuzzles.org/ambitious-science-teaching and explore this Google Slide deck that contains many resources designed to further your understanding of AST: https://docs.google.com/presentation/d/1WOUVmlm636_7i2l0GYa9JkX1TCK3NMdySfpxKN7IM7A/edit?usp=sharing

In this set of activities, high school students model changes in climate and their effects on international relations, investigate local climate impacts and solutions and observe global climate patterns and adaptations. Lessons may be standalone or done in series.

The original Native American story component lesson was developed as part of an Office of Superintendent of Public Instruction (OSPI) and Washington State Leadership and Assistance for Science Education Reform (LASER) project funded through an EPA Region 10 grant. The stories were told by Roger Fernandes of the Lower Elwha Klallam tribe. Mr. Fernandes has been given permission by the tribes to tell these stories.As these lessons and stories were shared prior to the adoption of the Washington State Science Learning Standards in 2013, there was a need to align these stories with the current science standards. This resource provides a current alignment and possible lesson suggestions on how these stories can be incorporated into the classroom. This alignment work has been funded by the NGSS & Climate Science Proviso of the Washington State Legislature as a part of North Central Educational Service District's award.

In this curriculum module, students in high school life science, marine science, and/or chemistry courses act as interdisciplinary scientists and delegates to investigate how the changing carbon cycle will affect the oceans along with their integral populations.

The oceans cover 70 percent of the planet and play a critical role in regulating atmospheric carbon dioxide through the interaction of physical, chemical, and biological processes. As a result of anthropogenic activity, a doubling of the atmospheric CO2 concentration (to 760 ppm) is expected to occur by the end of this century. A quarter of the total CO2 emitted has already been absorbed by the surface oceans, changing the marine carbonate system, resulting in a decrease in pH, a change in carbonate-ion concentrations, and a change in the speciation of macro and micronutrients. The shift in the carbonate system is already drastically affecting biological processes in the oceans and is predicted to have major consequences on carbon export to the deep ocean with reverberating effects on atmospheric CO2. Put in simple terms, ocean acidification is a complex phenomenon with complex consequences. Understanding complexity and the impact of ocean acidification requires systems thinking – both in research and in education. Scientific advancement will help us better understand the problem and devise more effective solutions, but executing these solutions will require widespread public participation to mitigate this global problem.

Through these lessons, students closely model what is occurring in laboratories worldwide and at Institute for Systems Biology (ISB) through Monica Orellana’s research to analyze the effect CO2 has on ocean chemistry, ecosystems and human societies. Students experiment, analyze public data, and prepare for a mock summit to address concerns. Student groups represent key “interest groups” and design two experiments to observe the effects of CO2 on seawater pH, diatom growth, algal blooms, nutrient availability, and/or shell dissolution.

Student groups work with manipulatives—pencils and trays—to maximize various quantities of a system. They work through three linear optimization problems, each with different constraints. After arriving at a solution, they construct mathematical arguments for why their solutions are the best ones before attempting to maximize a different quantity. To conclude, students think of real-world and engineering space optimization examples—a frequently encountered situation in which the limitation is the amount of space available. It is suggested that students conduct this activity before the associated lesson, Linear Programming, although either order is acceptable.

Food waste is a major contributor to greenhouse gas. Wasted food and the resources to produce that food are responsible for approximately 8% of global greenhouse gas emissions. In this storyline, students learn about the resources required to produce food through following the carbon cycle and discover how food waste contributes to climate change. They will also learn the farm to table transport chain as well as how to conduct a food waste assessment. Finally, the students will research solutions to the problem of food waste and, as a final project, present one solution that they have thoroughly researched that can be applicable to their community. For CTE teachers, this storyline provides the basic knowledge needed to develop a deep understanding of WHY reducing food waste is an important solution to climate change. There are several potential extensions that Family Consumer Science teachers can utilize as well as Ag teachers and even Business teachers. There is a partial list at the end of the learning progressions. 

As the climate is changing, one of the many consequences is sea level rise, which is not a standalone factor, but is closely related to erosion and extreme weather/storm conditions. The majority of coastal houses, recreational parks, and other coastal buildings were built as sturdy but stagnant structures that do not adjust well to the changing elements. Coastal homes have been collapsing into the ocean and restaurants have been destroyed by storm waves. The economic damage has been accumulating. In this storyline, students will explore the reasons behind sea level rise looking at thermal expansion, glacial ice melt, and sea ice melt. Students will examine real scenarios of coastal damage in Washington state and evaluate current city and tribal resilience plans. Finally, students will evaluate the constraints of existing challenges and propose strategies for solving these challenges.

El desperdicio de comida es uno de los principales contribuyentes a los gases de efecto invernadero. Los alimentos desperdiciados y los recursos para producirlos son responsables de aproximadamente el 8% de las emisiones mundiales de gases de efecto invernadero. En este caso, los estudiantes aprenden sobre los recursos necesarios para producir alimentos a través del ciclo del carbono y descubren cómo el desperdicio de alimentos contribuye al cambio climático. También aprenderán la cadena de transporte de la granja a la mesa y cómo llevar a cabo una evaluación de desperdicio de comida. Finalmente, los estudiantes investigarán soluciones al problema del desperdicio de comida y, como proyecto final, presentarán una solución que han investigado a fondo que puede ser aplicable a su comunidad. Para los maestros de CTE, este caso proporciona el conocimiento básico necesario para desarrollar una comprensión profunda de POR QUÉ reducir el desperdicio de comida es una solución importante para el cambio climático. Hay varias extensiones potenciales que los maestros de ciencias del consumo familiar pueden utilizar, así como los maestros de Agricultura e incluso los maestros de Negocios. Hay una lista parcial al final de las progresiones de aprendizaje.