Lecture: 4 hours/week
and
Possible Field Experience: approximately 4 hours/semester
In this course students will engage in a variety of activities such as lecture, small- and large-group discussion, field experiences, case studies, and team-based work.
- Course introduction: the importance of interweavings, interdependencies, and interconnections
- Basics of climate change science
- Radiant energy, solar and terrestrial radiation
- Greenhouse gases, their sources, effects, and changing concentrations in the atmosphere
- Comparative climate change over Earth's history
- Natural and anthropogenic forcings
- Climate data, models, and their predictions of possible futures
- Rethinking environmental knowledge (How do we "know" what we know?)
- Indigenous ecological knowledge traditions: perspectives on the environment and sustainability
- Philosopies of human-environment relations
- Impacts on natural systems
- Atmospheric responses, e.g. more extreme weather
- Land responses, e.g. continentality effect, glacier and permafrost loss, floods, slope failure, and retreat from shorelines
- Water responses, e.g. changes to sea level, oceanic circulation, and freshwater systems
- Biosphere responses, e.g. biodiversity and biome changes
- Impacts on human systems
- Migration and settlement patterns
- Water, food and agriculture
- Human health
- Geopolitical relations
- Patterns of production and trade
- Urban environments
- Climate justice: burdens and responsibilities
- Regional/spatial distributions and inequities
- Environmental racism
- Conversations, story-telling and communication
- Effective practices
- Understanding climate science denial/resistance
- Mitigation and adaptation
- Examples of global to local policies and regulatory strategies
- Assessing various approaches and agreements
- Grassroots, non-profit, and non-governmental movements
- Global, regional, and local case studies
- Defining goals and what constitutes success
At the conclusion of the course the successful student will be able to:
- Demonstrate understanding of basic interconnections and interdependencies among land, water, atmosphere, and biosphere (of which all living beings, including humans, are a part)
- Describe the key physical processes and interconnections of natural and anthropogenic climate change
- Demonstrate awareness and understanding of Indigenous forms of knowledge and values regarding environmental (specifically climate) change and sustainability, and be willing to take a two-eyed approach
- Explain the various impacts of climate change on human and natural systems at different spatial scales (global to local)
- Describe the socio-spatial impacts of the climate emergency on social inequities and social justice
- Think critically about and explain the scientific evidence for anthropogenic climate change to a general audience
- Demonstrate an understanding of the importance of communicating environmental change and climate science to promote intergenerational sharing and lifelong learning
- Critically evaluate mitigation and adaptation strategies, for example, concepts such as net zero, decarbonization, and economic and fiscal approaches
- Assess the effectiveness of various citizen-led climate action movements at global, regional, and local levels, and apply this learning to plan and create a climate action activity
Evaluation will be based on course objectives and will be carried out in accordance with the Douglas College Evaluation policy. Instructors may use a student’s record of attendance and/or level of active participation in the course as part of the student’s graded performance. Where this occurs, expectations and grade calculations regarding class attendance and participation will be clearly defined in the course outline. The instructor will provide a written course outline with specific criteria during the first week of classes.
An example of a possible evaluation scheme would be:
In-class exercises 10%
Field assignments 20%
Term Projects 25%
Exams 40%
Contribution/Participation 5%
Total 100%
Texts will be chosen from the following list, to be updated periodically. An instructor's Course Reader may be required.
- Allen, J. (2021). The New Climate Activism: NGO Authority and Participation in Climate Change Governance. Toronto: University of Toronto Press.
- Burch, S. L. and Harris. S. (2021). Understanding climate change: Science, policy and practice, Second Edition. Toronto: University of Toronto Press.
- Gergis, J. (2023). Humanity's Moment: A Climate Scientist's Case for Hope. Washington: Island Press.
- Gilbert, M. (Ed.) (2022). The Gwich'in Climate Report. Fairbanks: University of Alaska Press.
- Gobby, J. (2020). More Powerful Together: Conversations with Climate Activists and Indigenous Land Defenders. Winnipeg: Fernwood Publishing.
- Hayhoe, K. (2021). Saving Us: A Climate Scientist's Case for Hope and Healing in a Divided World. New York: One Signal Publishers/Atria
- Kennedy-Woodward, M. and Kennedy-Williams, P. (2023). You are Unstoppable! How to Understand Your Feelings About Climate Change and Take Positive Action Together. London: Jessica Kingsley Publishers.
- Kimmerer, R.W. (2013). Braiding Sweetgrass. Minneapolis: Milkweed Editions.
- Kress, M. and Horn-Miller, K. (Eds.) (2023). Land as Relation: Teaching and Learning through Place, People and Practices. Toronto: Canadian Scholars.
- Miller, D. (2020). Solved: How the World's Great Cities are Fixing the Climate Crisis. Toronto: University of Toronto Press.
- Snively, G. and Williams, W.L. (2016). Knowing Home: Braiding Indigenous Science with Western Science, Book 1. BC Campus Open Educational Resource. https://pressbooks.bccampus.ca/knowinghome/
Courses listed here must be completed either prior to or simultaneously with this course:
- No corequisite courses
Courses listed here are equivalent to this course and cannot be taken for further credit:
- No equivalency courses