Instructor Materials: Overview of the Renewable Energy and Environmental Sustainability Course

The overarching goal of this course is to teach basic geosciences principles through an exploration of environmentally sustainable technologies.

Supporting Course Goals:

Students will apply the geoscience principles underlying, and social implications of, implementing new technologies to address issues of energy and resource scarcity and environmental sustainability.
Students will use both data they collect themselves and data collected and published by others to test the efficacy of various green technologies.
Students will apply their knowledge to develop sustainable energy and resource conservation strategies as individuals and as a society.
Students will use learner-centered techniques to organize geoscience and social science data, and to analyze and present case studies relevant to the adoption of green technologies.
Students will learn how to develop meaningful questions about energy, resources, society, and sustainability that address higher levels of cognition.

Show InTeGrate Goals this Course Addresses

InTeGrate Goals this Course Addresses

This course was developed under the InTeGrate program which seeks to provide innovative geoscience education for college students. Below are the InTeGrate goals and brief comments on how each is addressed in this course. A more detailed treatment of goals and alignment with evaluation is provided in a matrix at: Alignment of Learning Outcomes and Course Goals (Excel 39kB Jun28 17)

Use geoscience-related grand challenges facing society: Students will explore the grand challenge of how society can use clean energy technologies as part of the response to global climate change.
Develop students' ability to address interdisciplinary problems: The course examines the various technologies from a broad, interdisciplinary approach. Modules include history, social science, physics, and geoscience.
Improve student understanding of the nature and methods of geoscience and developing geoscientific habits of mind: The modules are designed for the students to understand the various technologies in the light of geoscience concepts. The hands-on exercises encourage investigation of geoscience principles related to each technology.
Make use of authentic and credible geoscience data: All of the modules provide opportunities for students to work with geoscience or related data. This includes data they generate themselves in experiments as well as published geoscience data.
Incorporate systems thinking: The modules are designed so the students understand the technologies as part of a large and dynamic world, which requires systems thinking. The course is built around understanding and application of various sustainable technologies. Each technology can be taught as a system, and the role of that technology can also be taught as part of the greater Earth system.

Jump down to: Teaching and Learning Approach | Course Outline | Making the Materials Work

Course Description

This course will explore a variety of sustainable technologies with emphasis on understanding the fundamental scientific properties underlying each. Students will also examine appropriate applications of the technologies and evaluate their use with environmental and economic considerations.

Students attending college in the United States today grew up in a culture that is transitioning to a new understanding of the need to move toward a future built upon environmental sustainability. A large element of this shift involves embracing appropriate technologies to facilitate post-industrial age lifestyles. The responsibility for implementing the revolution in the way we relate to our environment will fall squarely on the shoulders of the current generation of college students. In their lifetime they will participate in the most important restructuring of society since the dawn of the industrial revolution.

Most college students possess sufficient basic knowledge to associate many emerging technologies with the concept of sustainability. They are excited about adopting new approaches to replace the "dirty" solutions of the past. On a superficial level they understand the "green-ness" of such things as wind turbines, photovoltaic solar cells, and hybrid electric vehicles. Yet few students outside of specialized STEM disciplines comprehend: 1) The basic principles governing these technologies; 2) The environmental implications associated with each, and; 3) The social and economic implications of implementing sustainable alternatives. They also lack direct exposure to these technologies; few have been in a building powered by solar energy or have driven a hybrid-electric car. Absent a deeper understanding of and direct experience with these emerging technologies, today's students will be unable to fully contribute to and participate in the revolution toward sustainability.

Green technologies are only important in the context of solving real-world problems. Each technology will be taught so as to address how it fits into solving the puzzle of sustainability.

The target audience of this course is any college student on campus. This philosophy embraces the notion that courses populated by academically diverse students will produce a better outcome for all involved. Since the course draws on many different disciplines to develop a broad and deep understanding of the issues, it is natural to expect the course to attract a diverse enrollment.

One goal of this class is to use green technology as a platform to teach basic scientific principles. While successful STEM students master enough basic science and mathematics to fulfill their curriculum requirements, experience often reveals the great difficulty they have in applying what they have learned to anything other than the memorized textbook examples. The non-STEM majors typically suffer from science and math phobia, and find difficulty in using science and quantification to understand the world around them. This course teaches the technology first and then introduces the underlying science.

This allows students to first develop interest in the topic, and that makes the ensuing formulas and theories that much more palatable. Math and science instruction so often fails because we teach it backward. We say, "learn these principles and equations, and once you get into the club we will show you their application and why they are so cool." Of course, students soon forget the mostly meaningless formulas after the course. Geosciences-based instruction offers the "real world (by definition!)" opportunity to illustrate fundamental principles of math and science in a way that should stick with the student. A hands-on experiment with different-colored solar collectors facilitates more deep and sustained learning about light and the electromagnetic spectrum than a well-crafted PowerPoint lecture.

Teaching and Learning Approach

This course is based on the discovery approach to learning and is designed to work in a modern "flipped classroom" as explained on the Course Design and Structure page. However, one may certainly use these materials in the more traditional instructor-centered approach. Each technology examined will address the following questions:

1. What is its purpose?
2. How does it work?
3. What are the basic underlying scientific principles?
4. What are the environmental consequences (good and bad) of its adoption?
5. What are the social and economic consequences of its adoption?
6. What factors inhibit its adoption?
7. How does this technology compare with traditional technologies and other alternative green technologies?

Course Outline

Explore:
Course Design
and Structure » This course on renewable energy for environmental sustainability uses a modular approach, with each module designed to be completed within a single two- to three-hour class period. Modules 1–4 focus on the management of thermal energy. Modules 5–7 introduce concepts regarding electricity, light, and mechanical energy. Module 7 uses the concepts from the preceding lessons to explore conservation and efficiency. Module 9 looks at technologies for cleaner automotive transportation. Module 10 ties together concepts of energy with resource conservation through an investigation of composting toilets as an alternative to septic and wastewater treatment systems. All modules include geoscience components.