Article ID: | iaor20122727 |
Volume: | 44 |
Issue: | 3 |
Start Page Number: | 301 |
End Page Number: | 311 |
Publication Date: | May 2012 |
Journal: | Energy Policy |
Authors: | Denholm Paul, King Jeffrey C, Kutcher Charles F, Wilson Paul P H |
Keywords: | nuclear power, sustainability, emissions, carbon, United States, energy storage |
Both renewable and nuclear energy can provide significant contributions to decarbonizing the electric sector. However, a grid employing large amounts of wind and solar energy requires the balance of the system to be highly flexible to respond to the increased variability of the net load. This makes deployment of conventional nuclear power challenging both due to the technical challenges of plant cycling and economic limits of reduced capacity factor. In the United States nuclear power plants generally provide constant, base load power and are most economic when operated at constant power levels. Operating nuclear power plants in load‐following modes decreases the plants' annual energy output and increases the levelized cost of energy, decreasing economic competitiveness. One possible solution is to couple thermal energy storage to nuclear power plants. This would enable the reactor to remain at nearly constant output, while cycling the electrical generator in response to the variability of the net load. This paper conceptually explores combinations of wind, solar, and nuclear that can provide a large fraction of a system's electricity, assuming the use of thermal energy storage that would allow nuclear power to provide load following and cycling duty while operating at a constant reactor power output.