C42B-07
Integrating snow albedo from the Airborne Snow Observatory into the distributed energy balance snowmelt model iSnobal
Thursday, 17 December 2015: 11:50
3005 (Moscone West)
McKenzie Skiles1, Thomas H Painter1, Danny G Marks2 and Andrew R Hedrick3, (1)NASA Jet Propulsion Laboratory, Pasadena, CA, United States, (2)USDA Agriculture Research Serv, Boise, ID, United States, (3)USDA Agricultural Research Service New England Plant, Soil and Water Research Laboratory, East Wareham, MA, United States
Abstract:
Since 2013 the Airborne Snow Observatory (ASO) has been measuring spatial and temporal distribution of both snow water equivalent and snow albedo, the two most critical properties for understanding snowmelt runoff and timing, across key basins in the Western US. It is generally understood that net solar radiation (as controlled by variations in snow albedo and irradiance) provides the energy available for melt in almost all snow-covered environments. Until now, sparse measurements have restricted the ability to utilize measured net solar radiation in energy balance models, and current process simulations and model prediction of albedo evolution rely on oversimplifications of the processes. Data from ASO offers the unprecedented opportunity to utilize weekly measurements of spatially extensive spectral snow albedo to constrain and update snow albedo in a distributed snowmelt model for the first time. Here, we first investigate the sensitivity of the snow energy balance model SNOBAL to prescribed changes in snow albedo at two instrumented alpine catchments: at the point scale across 10 years at Senator Beck Basin Study Area in the San Juan Mountains, southwestern Colorado, and at the distributed scale across 25 years at Reynolds Creek Experimental Watershed, Idaho. We then compare distributed energy balance and snowmelt results across the ASO measurement record in the Tuolumne Basin in the Sierra Nevada Mountains, California, for model runs with and without integrated snow albedo from ASO.