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Reconstructing the natural hydrology of the San Francisco Bay - Delta watershed
Hydrology and Earth Systems and Sciences
  • P. Fox, Independant Consulting Engineer
  • P.H. Hutton, Metropolitan Water District of Southern California
  • D.J. Howes, California Polytechnic State University - San Luis Obispo
  • A.J. Draper, MWH Americas Inc.
  • L. Sears, Independant Researcher
Publication Date
10-22-2015
Abstract
We evaluated the impact of landscape changes on the amount of delta outflow reaching San Francisco Bay. The natural landscape was reconstructed and water balances were used to estimate the long-term annual average delta outflow that would have occurred under natural landscape conditions if the climate from 1922 to 2009 were to repeat itself. These outflows are referred to as natural delta outflows and are the first published estimate of natural delta outflow. These natural delta outflows were then compared with current delta outflows for the same climate and existing landscape, including its re-engineered system of reservoirs, canals, aqueducts, and pumping plants. This analysis shows that the long-term, annual average delta outflow under current conditions is consistent with outflow under natural landscape conditions. The amount of water currently used by farms, cities, and others is about equal to the amount of water formerly used by native vegetation. Development of water resources in California’s Central Valley transferred water formerly used by native vegetation to new beneficial uses without substantially reducing the longterm annual average supply to the San Francisco Bay–Delta estuary. Based on this finding, it is unlikely that observed declines in native freshwater aquatic species are the result of annual average delta outflow reductions.
Publisher statement
Published by European Geosciences Union
Citation Information
P. Fox, P.H. Hutton, D.J. Howes, A.J. Draper, et al.. "Reconstructing the natural hydrology of the San Francisco Bay - Delta watershed" Hydrology and Earth Systems and Sciences Vol. 19 (2015) p. 4257 - 4274
Available at: http://works.bepress.com/djhowes/15/