Building a Course on Global Sustainability using the grand challenges of Energy-Water-Climate

GEOL1600: Global Sustainability: Managing the Earth's Resources is a lower division integrated science course at the University of Wyoming that fulfills the university's science requirement. Course content and context has been developed using the grand challenge nexus of energy-water-and climate (EWC). The interconnection of these issues, their social relevance and timeliness has provided a framework that gives students an opportunity to recognize why STEM is relevant to their lives regardless of their ultimate professional career choices. The EWC nexus provides the filter to sieve the course's STEM content. It also provides an ideal mechanism by which the non-STEM perspectives important in grand challenge solutions can be seamlessly incorporated in the course. Through a combination of content and context, the relevance of these issues engage students in their own learning. Development of the course followed the Grand Challenge Scientific Literacy (GCSL) model independently developed by the author and two colleagues at the University of Wyoming. This course model stresses science principles centered on the nature of science (e.g., fundamental premises, habits of mind, critical thinking) and unifying scientific concepts (e.g., methods and tools, experimentation, modeling). Grand challenge principles identify the STEM and non-STEM concepts needed to understand the grand challenges, drawing on multiple STEM and non-STEM disciplines and subjects (i.e., economics, politics, unintended consequences, roles of stakeholders). Using the EWC nexus filter and building on the Grand Challenge Principles, specific content included in the course is selected is that most relevant to understanding the Grand Challenges, thereby stressing content depth over breadth. Because quantitative data and reasoning is critical to effectively evaluating challenge solutions, QR is a component of nearly all class activities, while engineering and technology aspects of grand challenges are explicitly stressed. Running concurrently through the course is a consideration of personal perspectives and their influence on student learning, particularly for controversial subjects. Organizationally, the course consists of three one hour lectures and a two hour lab each week. The lectures are used to introduce content and prepare the knowledge base students need for lab. Complementing traditional lectures are lecture worksheets (short activities applying topics previously presented in lecture) and lecture activities (more involved exercises that present a problem the students need to solve using previously learned scientific content and QR skills and tools). Labs focus on case studies set in global social contexts that are timely and relevant. Labs stress scientific skills (modeling groundwater flow) and also consider political and environmental issues, e.g. developing a policy to manage SO2 emissions from copper smelting. The ideas, concepts, educational materials and content developed in this course have been used as the basis for two Math Science Partnerships that have provided professional development for middle and high school science and math teachers and K-12 social, math and science teachers. These programs have worked with teachers to break down the barriers between disciplines and foster collaborative learning centered on socially relevant grand challenges.