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Toward Energy Geoscience Literacy Principles

Toward Energy Geoscience Literacy Principles. Bill Witherspoon Fernbank Science Center Dekalb County, GA School System Michael Wysession Washington University. Energy Literacy. Why do fuel prices rise (and fall)? Is “energy independence” a realistic goal?

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Toward Energy Geoscience Literacy Principles

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  1. Toward Energy Geoscience Literacy Principles Bill Witherspoon Fernbank Science Center Dekalb County, GA School System Michael Wysession Washington University

  2. Energy Literacy • Why do fuel prices rise (and fall)? • Is “energy independence” a realistic goal? • Will we run out of oil (natural gas, uranium…)? • How big a threat is climate change? • How serious are other energy pollution problems? • Can pollutants (CO2, nuclear waste) be safely disposed of underground?

  3. Geoscience Expertise Energy Geoscience Literacy EnergyLiteracy

  4. Three Mile Island - March 1979 “solar more dangerous than nuclear”

  5. Conversion and Delivery for Use Disposition of Waste Capture(Extraction) Use Energy Geoscience Literacy

  6. Impacts on Earth System Material Inputs Energy Geoscience Literacy Impacts on Earth System (Context Over Time) Conversion and Delivery for Use Disposition of Waste Capture(Extraction) Use

  7. Earth Science Literacy: Building Community Consensus Michael Wysession, Chair - Washington University David Budd - University of Colorado Karen Campbell - National Center for Earth-surface Dynamics Martha Conklin - University of California, Merced Nicole LaDue, Jill Karsten, Lina Patino - NSF Gary Lewis - GSA Robert Raynolds - Denver Museum of Science and Nature Robert W. Ridky - USGS Robert Ross - PRI John Taber - IRIS Barbara Tewksbury - Hamilton College Peter Tuddenham, Tina Bishop, William Bragg - College of Exploration

  8. Process May - Two-week asynchronous online workshop May 11-23, 2008 ~150 invited scientist participants ~200 scientist and educator observers

  9. Process May - Two-week asynchronous online workshop May 11-23, 2008 ~150 invited scientist participants ~200 scientist and educator observers July - Writing Workshop July 21-23, 2008 Washington University, St. Louis MO 35 scientists and educators from academia, K-12, agencies August / September – Committee/July participants comment on draft document October - November - Presentation at GSA; Community comment on draft document; Incorporation of 1st-round comments December - Presentation at AGU; Community comment on 2nd draft document

  10. Process of Earth Science 1. Earth Science explores our planet Earth is Old 2. Earth is 4.6 billion years old Earth = Complex Systems 3. Earth is a complex system of interactions between rock, water, air and life Ocean Climate Changing “Geosphere” 4. Earth is a continuously changing planet Atmosphere Others? Water <--> Earth 5. Earth is the water planet Life <--> Earth 6. Life evolves on a dynamic planet and continuously modifies Earth Humans <--> Earth Humans <-- Earth 7. Humans depend on Earth for resources 8. Humans are threatened by Earth’s Natural Hazards Humans --> Earth 9. Humans have become a significant agent of change on Earth

  11. Process of Earth Science 1. Earth Science explores our planet Earth is Old 2. Earth is 4.6 billion years old Earth = Complex Systems 3. Earth is a complex system of interactions between rock, water, air and life Ocean Climate Changing “Geosphere” 4. Earth is a continuously changing planet Atmosphere Others? Water <--> Earth 5. Earth is the water planet Life <--> Earth 6. Life evolves on a dynamic planet and continuously modifies Earth Humans <--> Earth Humans <-- Earth 7. Humans depend on Earth for resources 8. Humans are threatened by Earth’s Natural Hazards Humans --> Earth 9. Humans have become a significant agent of change on Earth

  12. Big Idea #7: Humans depend on Earth for resources.

  13. Supporting Concepts 7.3 Natural resources are finite. 7.4 Resources are distributed unevenly around the planet. 7.7 Fossil fuels and uranium currently provide most of our energy resources. 7.8 Oil and natural gas are unique resources that are central to modern life in many different ways. 7.9 Earth scientists develop new technologies to extract resources while reducing the pollution, waste, and ecosystem degradation caused by extraction. Big Idea #7: Humans depend on Earth for resources.

  14. Big Idea #9: Humans have become a significant agent of change on Earth.

  15. Big Idea #9: Humans have become a significant agent of change on Earth. Supporting Concepts • 9.1 Human activities significantly change the rates of many Earth processes. • 9.2 The geologic record distinguishes natural and human influences on Earth’s systems, providing the basis for understanding rates of global change over time. • 9.4 Humans cause global climate change through fossil fuel combustion, land-use changes, agricultural practices, and industrial processes. • 9.5 Humans affect the quality, availability, and distribution of Earth's water through the modification of streams, lakes, and groundwater. • 9.9 Earth scientists document and seek to understand the impacts of humans on global change involving the land, water, and air over short and long time spans.

  16. Why do fuel prices rise (and fall)? • Is “energy independence” a realistic goal? • Will we run out of oil (natural gas, uranium…)? 7.4 Resources are distributed unevenly around the planet. This is a result of how and where geologic processes have occurred in the past, and has extremely important social, economic and political implications. • Although resources are finite, reserve estimates are often revised upward. This can result from new discoveries, improved extraction techniques, and higher commodity prices. • Oil and natural gas occur in sedimentary basins, locations where sedimentary rocks are thousands of feet thick. These vary greatly in oil and gas potential. • Oil and natural gas resources can be proven only by drilling, after extensive study. Complex geologic circumstances determine whether a well will be a discovery or a dry hole. • Much of Earth’s remaining oil will be expensive to recover. Oil in depleted fields, oil shale, and tar sands will require significant energy to extract, and most new areas for exploration are in difficult environments such as the Arctic or deep water.

  17. How big a threat is climate change? 9.2 The geologic record distinguishes natural and human influences on Earth’s systems, providing the basis for understanding rates of global change over time. Evidence for human influences on global changes is found in fossil distributions, ice cores, lake and ocean sediments, and soils. • The geologic record documents that variables including global temperature, greenhouse gas levels, ocean chemistry, and sea level are interrelated as predicted by physical models. Each variable has reached much higher and lower levels than today; however, since the industrial revolution, several variables have undergone unusually rapid change. • The geologic record contains examples of tipping points, in which gradual change in one variable may have caused sudden major shifts in the Earth system. • Changes in the Earth system drive the evolution of life. Although life as a whole has been resilient, many groups have disappeared due to mass extinction as conditions changed.

  18. How serious are other energy pollution problems? • Can pollutants (CO2, nuclear waste) be safely disposed of underground? • Waste disposed of underground may resurface, for example in the water supply. The risk varies greatly depending upon geologic conditions. In general, fractures in rock make movement more difficult to predict. • Over time spans greater than hundreds of years, the risk of waste returning to the surface becomes more difficult to predict. Predictive models are only as good as the quality of data concerning slow processes and infrequent events (for example, slow chemical reactions, thousand-year floods, earthquakes and volcanic eruptions). • 9.5 Humans affect the quality, availability, and distribution of Earth's water through the modification of streams, lakes, and groundwater. … Pollution from sewage runoff, agricultural practices, and industrial processes, reduce water quality, and overuse reduces water availability.

  19. Energy Geoscience Literacy Discussion

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