1. Nuclear Power Isar Plant - Germany Diablo Canyon - California

2. Nuclear Power – The facts Nuclear power - like wind, hydro and solar energy - emits no carbon dioxide Nuclear power - like wind, hydro and solar energy - emits no carbon dioxide Proven technology with base-load electrical power production capacity >1,000MW/plant Proven technology with base-load electrical power production capacity >1,000MW/plant Used worldwide; good safety track record despite TMI and Chernobyl Used worldwide; good safety track record despite TMI and Chernobyl - Much safer than coal-fired power both from an industrial (mining) and public health perspective There are significant issues: There are significant issues: Environmental impacts, costs, aging plants, waste disposal, nuclear proliferation, security, and public safety perceptions Environmental impacts, costs, aging plants, waste disposal, nuclear proliferation, security, and public safety perceptions

3. Nuclear Power Projections More nuclear plants may be needed to meet growing electric power demand More nuclear plants may be needed to meet growing electric power demand - International Energy Agency estimates renewable plants will only reach 6% of worldwide supply capacity by 2030 - Population increase from ~6.5B to 9B by 2100 - Standard of living rising across the globe with higher electrical demand – will double by 2050 - Nuclear energy production likely to continue to grow globally – especially in light of controls being placed on carbon emissions

4. Nuclear Worldwide 2007: 439 commercial reactors in 30 countries; 372,000 MW - Efficiency improving in both design & operation - Newer plants more efficient >1,000 MW capacity - Nuclear reactors currently supply 16% world’s power - 2,625 billion KWH in 2005; ~30% produced in the US As of 2001 Source: World Nuclear Association US 2005 total: 97,400MW cap. 782 billion KWH

5. How does it compare?

6. Nuclear Power - How it works

7. Uranium Mining Canada (25%), Australia (19%), Kazakhstan (16%) are world’s largest uranium ore producers (U.S. 4%) Canada (25%), Australia (19%), Kazakhstan (16%) are world’s largest uranium ore producers (U.S. 4%) Removal methods: Removal methods: - Underground 41% - Open pit 24% - In situ leach (ISL) 26% - By-product 9% Environmental & Health Risks Environmental & Health Risks - Land use impacts - Waste impacts - Operational risks - Health risks Highland ISL Mine, Wyoming Source: World Nuclear Association McArthur River Mine Canada

8. Nuclear Fuel Cycle Each fuel pellet = energy of 150 gallons of oil Each fuel pellet = energy of 150 gallons of oil - Pellets encased in metal tubes bundled into a fuel assembly Spent fuel is a hazardous radioactive waste Spent fuel is a hazardous radioactive waste - US: No pathway to disposal; spent fuel is stored in pools or casks at power plant sites - Proposed U.S. disposal site Yucca Mountain, Nevada dropped 2/09 - Other countries reprocess fuel to remove Pu-238 to use as fuel (closed fuel cycle); more efficient, creates less waste, but increases nuclear proliferation risks

9. U.S. Nuclear Power U.S. world’s largest supplier of nuclear power U.S. world’s largest supplier of nuclear power Nuclear power accounts for 20% of the electrical power generated in the U.S. Nuclear power accounts for 20% of the electrical power generated in the U.S. Currently, there are 66 power plants consisting of 104 operating nuclear reactors Currently, there are 66 power plants consisting of 104 operating nuclear reactors - 787 Billion KWhs electricity produced in 2006 - No new licenses since TMI accident (1979) - NRC has accepted applications for 11 new units and are expecting applications for up to 33 new units by 2010 Current plants avoids 700 million metric tons of carbon emissions annually vs. fossil fuel plants Current plants avoids 700 million metric tons of carbon emissions annually vs. fossil fuel plants ENW Columbia Generating Station 1250 MW Hanford, WA

10. It’s Expensive - The Real Costs Energy Policy Act of 2005 provides significant cost benefits to nuclear industry Energy Policy Act of 2005 provides significant cost benefits to nuclear industry - Tax credits up to $125 million for 8 years - Loan guarantees up to 80% of plant costs – initially limited to $2 billion fund but industry lobbying to expand to $50+ billion - Federal insurance against regulatory delays - Other subsidies include local tax incentives and limits on liability for accidents Costs of decommissioning contaminated plants and waste disposal are not reflected in cost projections for new plants Costs of decommissioning contaminated plants and waste disposal are not reflected in cost projections for new plants Long history of significant cost increases and overruns in nuclear power plant construction Long history of significant cost increases and overruns in nuclear power plant construction

11. Zero Carbon Construction Costs* Nuclear Plant 1,000+ MWe $5B to 9B Big Horn 200 MW 11,000 Acres, ~$130M Klicitat County, WA 5X 5X Waldpolenz Germany 250 acres, 40MW, $185M 25X 25X Kramer Junction CA Solar Trough, 150 MW, 1000 acres, ~$750M McNeil Biomass Plant Burlington, VT 50 MW, $67M 20X *Does not include waste disposal & decommissioning 6.7X 100X South Korean Uldolmok Tidal Plant 1MW, ~$9.9M 1,000X $9.9B $5B $2.8B $1.4B $4.6B $1B BEST BUY PS-10 Solar Tower Spain 10 MW, 150 acres, $28M * New 1000 MW Coal Plant ~ $4B

12. #1 - Increase efficiency and reduce use - - we can’t continue increasing demand without consequences (the cheapest plant is the one we don’t build!) Government needs to favor the most promising options to reduce carbon emissions - - Revisit our current subsidy strategies - - Increasing investment and deployment of renewable power plants will increase cost competitiveness - - Europe is making major investments to transition to 20% renewable power by 2020 Many current nuclear plants are operating beyond their original design life - - How long can they operate and how will we replace the 20% of our power they produce? Build more? Wealthy nations must help developing nations build low (or zero) emissions power production How do we meet growing energy demands and reduce CO 2 emissions?

13. Where do we go from here? How do we keep our planet habitable? What do you think? Design the power infrastructure for your own city – make the decisions and compare the results online at: www.willyoujoinus.com www.willyoujoinus.com Sponsored by The Economist Group and Chevron www.willyoujoinus.com