TY - JOUR
T1 - Snow surface energy and mass balance in a warm temperate climate mountain
AU - Sade, Rotem
AU - Rimmer, Alon
AU - Litaor, M. Iggy
AU - Shamir, Eylon
AU - Furman, Alex
N1 - Publisher Copyright:
© 2014 Elsevier B.V.
PY - 2014/11/7
Y1 - 2014/11/7
N2 - In warm temperate mountain regions where water is often scarce vapor losses from the snow-surface can substantially limit snowmelt. Therefore, understanding the key snow dynamic processes that affect water availability in these mountains is essential. We studied the snowpack energy and mass balance in Mt. Hermon, Israel using a comprehensive field campaign during 2010/11. We analyzed the snowpack energy and mass balance during the winter of 2010/11 in a Deep Snow Patch (DSP), and in the Bulan valley experiment area (BVEA), where both windswept locations and lee-side (deep snowpack) locations were examined. We applied for this analysis an energy and mass balance snow model that was forced by input from two meteorological stations. The calibration of the model for the DSP and BVEA was based on surveyed snow water equivalent data, and melting cycles that were measured with time-lapse cameras, respectively. Using a step function to describe wind speed over the DSP we showed that the turbulent fluxes were influenced by changes in snowpack height. The turbulent fluxes were found as the dominant energy fluxes at the snow-surface. During winter, vapor losses varied between 46% and 82% of the total ablation. Consequently, latent heat flux consumed much of the available energy at the snow-surface, greatly limiting melting rate to 1mmday-1. During spring, vapor flux was positive which enhanced condensation, resulting in an average melting flux of 86 mm day-1. The spatial variation in the vapor flux at the BVEA due to terrain orientation yield variation in space of the available water at the bottom of the snowpack.
AB - In warm temperate mountain regions where water is often scarce vapor losses from the snow-surface can substantially limit snowmelt. Therefore, understanding the key snow dynamic processes that affect water availability in these mountains is essential. We studied the snowpack energy and mass balance in Mt. Hermon, Israel using a comprehensive field campaign during 2010/11. We analyzed the snowpack energy and mass balance during the winter of 2010/11 in a Deep Snow Patch (DSP), and in the Bulan valley experiment area (BVEA), where both windswept locations and lee-side (deep snowpack) locations were examined. We applied for this analysis an energy and mass balance snow model that was forced by input from two meteorological stations. The calibration of the model for the DSP and BVEA was based on surveyed snow water equivalent data, and melting cycles that were measured with time-lapse cameras, respectively. Using a step function to describe wind speed over the DSP we showed that the turbulent fluxes were influenced by changes in snowpack height. The turbulent fluxes were found as the dominant energy fluxes at the snow-surface. During winter, vapor losses varied between 46% and 82% of the total ablation. Consequently, latent heat flux consumed much of the available energy at the snow-surface, greatly limiting melting rate to 1mmday-1. During spring, vapor flux was positive which enhanced condensation, resulting in an average melting flux of 86 mm day-1. The spatial variation in the vapor flux at the BVEA due to terrain orientation yield variation in space of the available water at the bottom of the snowpack.
KW - Mt. Hermon
KW - Snowpack energy and mass balance
KW - Turbulent fluxes
KW - Vapor losses
KW - Warm temperate climate
UR - http://www.scopus.com/inward/record.url?scp=84906739328&partnerID=8YFLogxK
U2 - 10.1016/j.jhydrol.2014.07.048
DO - 10.1016/j.jhydrol.2014.07.048
M3 - 文章
AN - SCOPUS:84906739328
SN - 0022-1694
VL - 519
SP - 848
EP - 862
JO - Journal of Hydrology
JF - Journal of Hydrology
IS - PA
ER -