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Climate change is arguably the greatest challenge of our time. Human activity has already warmed the planet by one degree Celsius relative to pre-industrial times, and we are feeling the effects through record heat waves, droughts, wildfires and flooding. If we continue to burn fossil fuels at the current rate, the planet will reach two degrees of warming by 2050—the threshold that many scientists have identified as a dangerous tipping point. What is the science behind these projections?
Join climate science expert Michael Mann to learn about the basic scientific principles behind climate change and global warming. We need to understand the science in order to solve the broader environmental, societal and economic changes that climate change is bringing.
By the end of this course, you will:
- Develop a deep scientific understanding of HOW the climate system has been changing;
- Articulate WHY the climate system is changing;
- Understand the nature of these changes;
- Develop a systems thinking approach to analyzing the impacts of climate change on both natural and human systems.
The course covers the basic principles of atmospheric science, methods of climate data collection and tracking of greenhouse gas emissions. It introduces basic climate modeling and explores the impact of various greenhouse gas emissions scenarios. Finally, it outlines the impacts of climate change on environmental, social, economic and human systems, from coral reefs and sea level rise to urban infrastructure. The course follows the general outline of the 5th Assessement Report of the United Nations Intergovernmental Panel on Climate Change.
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Module 1: Introduction to Climate and Climate Change
1.0 Course Introduction
1.1 What is climate change
1.2 What should we care about climate change?
1.3 Overview of the climate system: How is the climate system constructed?
1.4 Overview of the climate system: How do energy balances work?
1.5 Overview of the climate system: Global circulation systems
1.6 Other fundamental principles: Feedback mechanisms and the carbon cycleModule 2: Observing and Measuring Anthropogenic Climate Change
2.1 Changes in atmospheric greenhouse gases
2.2 Modern surface temperature trends
2.3 The oceans
2.4 Extreme weather
2.5 Sea ice, glaciers and global sea level
2.6 Paleoclimate evidence of climate changeModule 3: Modeling the Climate System: The Basics
3.1 Introduction to climate modeling
3.2 Expressing a zero-dimensional energy model as a linear equation
3.3 0d-EBM demonstration
3.4 Estimating climate sensitivityModule 4: Modeling the Climate System: Advanced
4.1 One-dimensional energy balance models
4.2 Case Study: Using a one-dimensional EBM to model the ice ages
4.3 General circulation models
4.4 Validating climate models
4.5 Detecting climate change
4.6 Interpreting climate sensitivityModule 5: Carbon Emission Scenarios
5.1 Emissions Scenarios
5.2 Stabilizing CO2 concentrationsModule 6: Applying Climate Models: Projected Changes in the Climate System
6.1 Surface temperature projections
6.2 Projected changes in global precipitation and drought
6.3 Atmospheric and oceanic circulation changes
6.4 The melting cryosphere
6.5 Sea level rise projections
6.6 Tropical cyclone and hurricane projections
6.7 Extreme weather projectionsModule 7: Climate Change Impacts: The Future for People and Planet
7.1 Carbon cycle feedbacks
7.2 Sea level rise and coastal impacts
7.3 Ecosystems and biodiversity
7.4 Shifting water and food resources
7.5 Human health impacts
7.6 Security concerns
7.7 Tipping pointsModule 8: What Is Our Path Forward?
8.1 Geoengineering: A scientist’s perspective, Part 1
8.2 Geoengineering: A scientist’s perspective, Part 2
8.3 Emissions reductions: The only viable way forward
8.4 Conclusion: A path of hope
