TY - JOUR
T1 - Estimates of glacier mass loss and contribution to streamflow in the Wind River range in wyoming
T2 - Case study
AU - Marks, Jeffrey
AU - Piburn, Jesse
AU - Tootle, Glenn
AU - Kerr, Greg
AU - Oubeidillah, Abdoul
N1 - Publisher Copyright:
© 2014 American Society of Civil Engineers.
PY - 2015/11/5
Y1 - 2015/11/5
N2 - The Wind River Range is a continuous mountain range, approximately 160 km in length, in west-centralWyoming. The presence of glaciers results in meltwater contributions to streamflow during the late summer (July, August, and September: JAS) when snowmelt is decreasing; temperatures are high; precipitation is low; evaporation rates are high; and municipal, industrial, and irrigation water are at peak demands. Thus, the quantification of glacier meltwater (e.g., volume and mass) contributions to late summer/early fall streamflow is important, given that this resource is dwindling owing to glacier recession. The current research expands upon previous research efforts and identifies two glaciated watersheds, one on the east slope (Bull Lake Creek) and one on the west slope (Green River) of theWind River Range, in which unimpaired streamflow is available from 1966 to 2006. Glaciers were delineated within each watershed and area estimates (with error) were obtained for the years 1966, 1989, and 2006. Glacier volume (mass) loss (with error) was estimated by using empirically based volume-area scaling relationships. For 1966 to 2006, glacier mass contributions to JAS streamflow on the east slope were approximately 8%, whereas those on the west slope were approximately 2%. The volume-area scaling glacier mass estimates compared favorably with measured (stereo pair remote sensed data) estimates of glacier mass change for three glaciers (Teton, Middle Teton, and Teepe) in the nearby Teton Range and one glacier (Dinwoody) in the Wind River Range.
AB - The Wind River Range is a continuous mountain range, approximately 160 km in length, in west-centralWyoming. The presence of glaciers results in meltwater contributions to streamflow during the late summer (July, August, and September: JAS) when snowmelt is decreasing; temperatures are high; precipitation is low; evaporation rates are high; and municipal, industrial, and irrigation water are at peak demands. Thus, the quantification of glacier meltwater (e.g., volume and mass) contributions to late summer/early fall streamflow is important, given that this resource is dwindling owing to glacier recession. The current research expands upon previous research efforts and identifies two glaciated watersheds, one on the east slope (Bull Lake Creek) and one on the west slope (Green River) of theWind River Range, in which unimpaired streamflow is available from 1966 to 2006. Glaciers were delineated within each watershed and area estimates (with error) were obtained for the years 1966, 1989, and 2006. Glacier volume (mass) loss (with error) was estimated by using empirically based volume-area scaling relationships. For 1966 to 2006, glacier mass contributions to JAS streamflow on the east slope were approximately 8%, whereas those on the west slope were approximately 2%. The volume-area scaling glacier mass estimates compared favorably with measured (stereo pair remote sensed data) estimates of glacier mass change for three glaciers (Teton, Middle Teton, and Teepe) in the nearby Teton Range and one glacier (Dinwoody) in the Wind River Range.
KW - Climate
KW - Glacier
KW - Mass
KW - Streamflow
UR - http://www.scopus.com/inward/record.url?scp=84946031160&partnerID=8YFLogxK
U2 - 10.1061/(ASCE)HE.1943-5584.0001050
DO - 10.1061/(ASCE)HE.1943-5584.0001050
M3 - Article
AN - SCOPUS:84946031160
SN - 1084-0699
VL - 20
JO - Journal of Hydrologic Engineering
JF - Journal of Hydrologic Engineering
IS - 8
M1 - 05014026
ER -