TY - JOUR
T1 - Near-term acceleration of hydroclimatic change in the western U.S.
AU - Ashfaq, Moetasim
AU - Ghosh, Subimal
AU - Kao, Shih Chieh
AU - Bowling, Laura C.
AU - Mote, Philip
AU - Touma, Danielle
AU - Rauscher, Sara A.
AU - Diffenbaugh, Noah S.
PY - 2013/10/16
Y1 - 2013/10/16
N2 - Given its large population, vigorous and water-intensive agricultural industry, and important ecological resources, the western United States presents a valuable case study for examining potential near-term changes in regional hydroclimate. Using a high-resolution, hierarchical, five-member ensemble modeling experiment that includes a global climate model (Community Climate System Model), a regional climate model (RegCM), and a hydrological model (Variable Infiltration Capacity model), we find that increases in greenhouse forcing over the next three decades result in an acceleration of decreases in spring snowpack and a transition to a substantially more liquid-dominated water resources regime. These hydroclimatic changes are associated with increases in cold-season days above freezing and decreases in the cold-season snow-to-precipitation ratio. The changes in the temperature and precipitation regime in turn result in shifts toward earlier snowmelt, base flow, and runoff dates throughout the region, as well as reduced annual and warm-season snowmelt and runoff. The simulated hydrologic response is dominated by changes in temperature, with the ensemble members exhibiting varying trends in cold-season precipitation over the next three decades but consistent negative trends in cold-season freeze days, cold-season snow-to-precipitation ratio, and 1 April snow water equivalent. Given the observed impacts of recent trends in snowpack and snowmelt runoff, the projected acceleration of hydroclimatic change in the western U.S. has important implications for the availability of water for agriculture, hydropower, and human consumption, as well as for the risk of wildfire, forest die-off, and loss of riparian habitat. Key Points Acceleration of decreases in western U.S. spring snowpack in next three decades Shifts toward earlier snowmelt, base flow, and runoff dates throughout the region Hydrological response is dominated by changes in temperature
AB - Given its large population, vigorous and water-intensive agricultural industry, and important ecological resources, the western United States presents a valuable case study for examining potential near-term changes in regional hydroclimate. Using a high-resolution, hierarchical, five-member ensemble modeling experiment that includes a global climate model (Community Climate System Model), a regional climate model (RegCM), and a hydrological model (Variable Infiltration Capacity model), we find that increases in greenhouse forcing over the next three decades result in an acceleration of decreases in spring snowpack and a transition to a substantially more liquid-dominated water resources regime. These hydroclimatic changes are associated with increases in cold-season days above freezing and decreases in the cold-season snow-to-precipitation ratio. The changes in the temperature and precipitation regime in turn result in shifts toward earlier snowmelt, base flow, and runoff dates throughout the region, as well as reduced annual and warm-season snowmelt and runoff. The simulated hydrologic response is dominated by changes in temperature, with the ensemble members exhibiting varying trends in cold-season precipitation over the next three decades but consistent negative trends in cold-season freeze days, cold-season snow-to-precipitation ratio, and 1 April snow water equivalent. Given the observed impacts of recent trends in snowpack and snowmelt runoff, the projected acceleration of hydroclimatic change in the western U.S. has important implications for the availability of water for agriculture, hydropower, and human consumption, as well as for the risk of wildfire, forest die-off, and loss of riparian habitat. Key Points Acceleration of decreases in western U.S. spring snowpack in next three decades Shifts toward earlier snowmelt, base flow, and runoff dates throughout the region Hydrological response is dominated by changes in temperature
KW - hydrological change
KW - hydrological modeling
KW - near-term projections
KW - snow cover
KW - western United States
UR - http://www.scopus.com/inward/record.url?scp=84887136751&partnerID=8YFLogxK
U2 - 10.1002/jgrd.50816
DO - 10.1002/jgrd.50816
M3 - Article
AN - SCOPUS:84887136751
SN - 2169-897X
VL - 118
SP - 10,676-10,693
JO - Journal of Geophysical Research: Atmospheres
JF - Journal of Geophysical Research: Atmospheres
IS - 19
ER -