乐播传媒

Racoviteanu, Adina听¹听;听Artan, Guleid听²听;听Brown, Molly听³听;听Shrestha, Mandira听⁴;听Bajracharya, Samjwal听⁵听;听Mool, Pradeep听⁶听;听Habib, Shahid听⁷听;听Tzortziou, Maria听⁸

¹听乐播传媒, Institute of Arctic and Alpine Research
²听USGS, Sioux Falls
³听NASA Goddard Space Flight Center
⁴听International Center for Integrated Mountain Development , Kathmandu
⁵听International Center for Integrated Mountain Development , Kathmandu
⁶听nternational Center for Integrated Mountain Development , Kathmandu
⁷听NASA Goddard Space Flight Center
⁸听NASA Goddard Space Flight Center

Snow and ice constitute an important component of the hydrologic regime of many large mountain ranges and regions, including the Himalayas. However, the hydrologic regime of Himalayan catchment basins, and the role of glaciers in the hydrologic regime of this mountain range (particularly their contribution to base 铿俹w) are not well understood. There are concerns about the impact of climate change on cryosphere as well as population growth, changing economic activity, land use change, rapid urbanization and inef铿乧ient water use on water resources. The HIMALA project, funded by the NASA鈥檚 Applied Sciences Program and the United States Agency for International Development (USAID), in collaboration with the Integrated Center for Integrated Mountain Development (ICIMOD), Nepal, addresses the urgent need for integrated snow and ice hydrology in the Himalaya. Speci铿乧 objectives are to: (i) introduce the use of NASA Earth Science products and models to ICIMOD and its member countries through collaboration with USAID and USGS and (ii) enhance the decision making capacity of ICIMOD and its member countries for management of water resources (铿俹ods, agricultural water) in the short (snow, rainfall) and the long-term (glaciers). Here we present methodology for a sub-basin hydrological model for Langtang watershed in Nepal, that includes modeling both snow and glacier-melt water contributions to stream铿俹w. Snow-and glacier-melt and out铿俹w is estimated using a spatially distributed version of the Utah Energy Balance (UEB) snow accumulation and ablation model, driven by remotely sensed data (TRMM, MERRA) and downscaled meteorological data. Glacier outlines and glacier characterization parameters (albedo and volume) are derived from Landsat (1980s to present) and ASTER data (2000 to present) and used as input to the UEB model. Snow cover and albedo are acquired from MODIS data. We estimate the relative contribution by snow and glacier melt to total melt, which is validated using discharge at various gauge stations in the watersheds. We use the Geospatial Stream Flow Model (GeoSFM) hydrologic model to simulate dynamics of runoff processes. Static input data are SRTM DEM, land cover, and soil information. The model is forced by daily estimates of precipitation and evaportranspiration to predict daily stream铿俹w at ground rain gauge stations. We are developing new user interfaces so that models will be easy to learn and can be used to monitor stream铿俹w in other basins in the region. ICIMOD will implement the prototype model in three large basins of the Himalaya (Koshi, Manas and Jhelum) ranging from east to west. This will provide a better understanding of the contribution of snow and ice to hydrology in the region with relation to the Asian monsoon.