GC33C-1300
Climate Change Impacts on Rivers and Implications for Electricity Generation in the United States

Wednesday, 16 December 2015
Poster Hall (Moscone South)
Ariel Miara1, Charles J Vorosmarty2, Jordan Macknick3, Fabio Corsi4, Stuart Michael Cohen3, Vincent Carroll Tidwell5, Robin L Newmark6 and Alex Prousevitch7, (1)CUNY City College, Environmental Crossroads Initiative, New York, NY, United States, (2)CCNY-Environ Crossroads Initi, New York, NY, United States, (3)National Renewable Energy Laboratory Golden, Golden, CO, United States, (4)CUNY City College, Department of Civil Engineering, New York, NY, United States, (5)Sandia Natl Laboratories, Albuquerque, NM, United States, (6)NREL, Golden, CO, United States, (7)University of New Hampshire Main Campus, Durham, NH, United States
Abstract:
The contemporary power sector in the United States is heavily reliant on water resources to provide cooling water for thermoelectric generation. Efficient thermoelectric plant operations require large volumes of water at sufficiently cool temperatures for their cooling process. The total amount of water that is withdrawn or consumed for cooling and any potential declines in efficiencies are determined by the sector’s fuel mix and cooling technologies. As such, the impact of climate change, and the extent of impact, on the power sector is shaped by the choice of electricity generation technologies that will be built over the coming decades. In this study, we model potential changes in river discharge and temperature in the contiguous US under a set of climate scenarios to year 2050 using the Water Balance Model-Thermoelectric Power and Thermal Pollution Model (WBM-TP2M). Together, these models quantify, in high-resolution (3-min), river temperatures, discharge and power plant efficiency losses associated with changes in available cooling water that incorporates climate, hydrology, river network dynamics and multi-plant impacts, on both single power plant and regional scales. Results are used to assess the aptness and vulnerability of contemporary and alternative electricity generation pathways to changes in climate and water availability for cooling purposes, and the concomitant impacts on power plant operating efficiencies. We assess the potential impacts by comparing six regions (Northeast, Southeast, Midwest, Great Plains, Southwest, Northwest as in the National Climate Assessment (2014)) across the US. These experiments allow us to assess tradeoffs among electricity–water–climate to provide useful insight for decision-makers managing regional power production and aquatic environments.