H13B-1496
Coastal Fog Sustains Summer Baseflow in Northern Californian Watershed
Monday, 14 December 2015
Poster Hall (Moscone South)
Michaella Chung, University of California Berkeley, Berkeley, CA, United States, Alexis Dufour, San Francisco Public Utilities Commission, San Francisco, CA, United States, Rebecca Leonardson, San Francisco PUC, San Francisco, CA, United States, Sally E Thompson, University of California Berkeley, Civil and Environmental Engineering, Berkeley, CA, United States and Todd E Dawson, University of California Berkeley, Center for Stable Isotope Biogeochemistry, Berkeley, CA, United States
Abstract:
The Mediterranean climate of Northern California imposes significant water stress on ecosystems and water resources during the dry summer months. During summer, frequently the only water inputs occur as occult precipitation, in the form of fog and dew. In this study, we characterized the role of coastal fog, a dominant feature of Northern Californian coastal ecosystems and a widespread phenomenon associated with deep marine upwelling in west coast, arid, and Mediterranean climates worldwide. We monitored fog occurrence and intensity, throughfall following canopy interception of fog, soil moisture, streamflow, and meteorological variables, and made visual observations of the spatial extent of fog using time-lapse imagery in Upper Pilarcitos Creek Watershed (managed by San Francisco Public Utilities Commission as part of the San Francisco area water supply). We adopted a stratified sampling design that captured the watershed’s elevation gradient, forest-edge versus interior locations, and different vegetation cover. The point-scale observations of throughfall inputs and transpiration suppression, estimated from the Penman equation, were upscaled using such watershed features and the observed fog “footprint” identified from the time-lapse images. When throughfall input and fog-induced transpiration suppression were incorporated into the operational watershed model, they improved estimates of summer baseflow, which remained persistently higher than could be explained without the fog effects. Fog, although providing relatively small volumetric inputs to the water balance, appears to offer significant relief of water stress throughout the terrestrial and aquatic components of the coastal Californian ecosystem and thus should be accounted for when assessing water stress availability in dry ecosystems.