1. Health Hazards of not Going Nuclear Understanding the “waste” issues Load Following capabilities – can they? Status of Nuclear Technology Economics

2. Radiation in perspective: –Living in Denver – add 350 mrem –TMI accident – add 1 mrem, replacement power for TMI2 produced by coal fire will result in more cancer deaths. –Annual background radiation (average) by natural sources in the US – 131 mrem –X-ray dose – about 100 mrem –Maximum amount of dose allowed to be received by someone who lived at a nuclear power plant boundary for 1 year – add 5 mrem –Coast to Coast jet flight – add 5 mrem

3. Source: "Life-Cycle Assessment of Electricity Generation Systems and Applications for Climate Change Policy Analysis," Paul J. Meier, University of Wisconsin-Madison, August, 2002

4. Generation optionGreenhouse gas emissions gram equiv CO 2 /kWh SO 2 emissions milligram/kWh NO x emissions milligram/kWh NMVOC milligram/kWh Particulate matter milligram/kWh Hydropower2-485-603-4205 Coal - modern plant790-1182700-32321+700-5273+18-2930-663+ Nuclear2-593-502-10002 Natural gas (combined cycle) 389-5114-15000+[1]13+-150072-1641-10+ Biomass forestry waste combustion 15-10112-140701-19500217-320 Wind7-12421-8714-5005-35 Solar photovoltaic13-73124-49016-3407012-190

6. Some radioactive isotopes last for thousands, millions of years. However, lethal doses of chlorine, phosgene, ammonia, cyanide produced in the US alone exceed those of nuclear “waste”. Also, some chemical poisons such as arsenic, lead and mercury last forever. Spent Fuel is recyclable and reusable. Interim dry storage – safe for decades. Long term depository – needed in the US and elsewhere. Reprocessing is expensive technology but Japan, France are using this now. Nuclear “waste” is preferable than waste from coal plants; radioactive wastes are manageable and can be secured whereas waste spewed into the atmosphere of fossil fired plants isn’t controlled. Coal plants have radioactive emissions due to radium and thorium in the coal. These radio-nuclides are dispersed into the atmosphere through the plant stack.

7. 59 operating nuclear reactors Just over 63 GWe capacity, supplying almost 80% of country’s demand In 2005 French electricity generation was 549 billion kWh net and consumption 482 billion kWh - 7700 kWh per person. Over the last decade France has exported 60-70 billion kWh net each year. France has some plants that follow load on a daily basis, as well as some which shutdown on the weekends only. French government policy starting in the mid 70’s was to expand rapidly the country's nuclear power capacity. Nuclear energy, with the fuel cost being a relatively small part of the overall cost, made good sense in minimizing imports and achieving greater energy security. France now claims a substantial level of energy independence and almost the lowest cost electricity in Europe. Over 90% of its electricity is nuclear or hydro.

8. Load following part of the original design of current operating fleet. Load following common in France. New reactor designs will be similarly designed - AP 1000 Example: –The AP1000 is designed to be capable of startup from cold shutdown to hot standby in 24 hours. –Similarly, it is capable of cooling down from reactor critical to the condition of refueling operation in 24 hours. –The AP1000 is designed for a 24-hour load cycle with the following profile (subject to achieving full power fuel conditioning at the beginning of the fuel cycle): Starting at 100% power, power ramps down to 50% power in 2 hours, Power remains at 50% for 2 to 4 hours, Power ramps up to 100% in 2 hours, Power remains at 100% for the remainder of the 24 hour cycle. –Also designed to respond to grid frequency changes. –In terms of power output modulation, the AP1000 is capable of satisfying peak- to-peak power demand changes of 10% of the plant rating at 2% of the plant rating per minute. This capability is provided within the power operating range of 15 to 100%.

9. In the US, the existing nuclear power plants are currently being operated as a base load source of power. Nuclear is most often the lowest cost choice of power. Nuclear energy provides only about 20% of the United States electricity – so being the lower cost choice, means it is not the first choice to back down. The nuclear industry has defined excellence, in part, as safely generating electricity as evidenced by good capacity and generation metrics. In other words, 100% capacity and generation are the hallmarks of good power plant operations. This focus drives the culture for keeping the plants on line as “base load”. The nuclear industry has a continuously improving culture, so there has been increasing preference to stay at 100%. Even so, grid controllers will ask plants to ramp given certain grid reliability needs, and the plant is required to respond and is in fact, capable of responding. There is less opportunity for human error when the plant operators are watching the plant parameters at 100% power versus having to manipulate the controls in moving the plant up or down in power.

10. Technology Type Power Output (MWe) Features GE- ABWR1350Many operating and being constructed in Japan. More passive features than existing BWR fleet in US. GE- ESBWR1500New design improves on ABWR. Spent fuel pool is secure. Has best seismic response capability. Completely passive design – less maintenance costs. Westinghouse – AP 1000 1100Passive design. AREVA – EPR1600Not passive but improves on safety, separation of redundant trains, double walled containment design. Largest footprint. Mitsubishi - APWR 1700Some new passive features.

12. Economies of Nuclear Operations are dependent on electric output, plant reliability, short refueling outages. Construction costs – Improvements in the process promise reduced or at least accurate construction cost projections. –World experience –One-step licensing process –Design Certification –Modular design, construction and installation –Refer to Joe Turnage slides at the June 28 th CEC workshop.