The sensitivity of snow-surface temperature equation to sloped terrain

Rotem Sade; Alon Rimmer; M. Iggy Litaor; Eylon Shamir; Alex Furman

doi:10.1016/j.jhydrol.2011.08.001

The sensitivity of snow-surface temperature equation to sloped terrain

Rotem Sade^*, Alon Rimmer, M. Iggy Litaor, Eylon Shamir, Alex Furman

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

6 Scopus citations

Abstract

Snow surface temperature (SST) is a key component in the calculation of snow-surface energy balance. Common snow models have adapted a specific linearized SST equation that accounts for the energy fluxes at the snow-atmosphere interface. An inspection of this widely used equation reveals that the areal units for three of the energy fluxes disregard the effect of sloped terrain and as a result presents a unit inconsistency in the equation. The objectives of this paper are to: (1) introduce a corrected SST equation; (2) discuss the role of the SST in snow models; and (3) assess the impact of this unit inconsistency on the simulation of snow variables in various climatic conditions. Meteorological observations were used to compare results that were obtained by implementation of the original and the corrected SST equations in a point energy and mass balance snow model. The calculated SST values in the original equation tend to be higher than the calculated value in the corrected equation. As a result when the original equation is used the SST-dependent energy fluxes (i.e. sensible heat, latent heat and net long-wave radiation) into the snow are lower, which yield lower melting rates. In conclusion, while the original SST equation might be applicable in snow models for gentle terrain, it introduces substantial biases in steep terrain. Therefore, it is conservatively recommended to consider the implementation of the corrected SST equation for snow model applications in mountainous terrain that are steeper than 15°.

Original language	English
Pages (from-to)	308-313
Number of pages	6
Journal	Journal of Hydrology
Volume	408
Issue number	3-4
DOIs	https://doi.org/10.1016/j.jhydrol.2011.08.001
State	Published - 13 Oct 2011
Externally published	Yes

Keywords

Energy balance
Mountainous terrain
Sloped terrain
Snow point model
Snow surface temperature
UEB

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10.1016/j.jhydrol.2011.08.001

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@article{6db7397fd69a406e9d59acc130f74577,

title = "The sensitivity of snow-surface temperature equation to sloped terrain",

abstract = "Snow surface temperature (SST) is a key component in the calculation of snow-surface energy balance. Common snow models have adapted a specific linearized SST equation that accounts for the energy fluxes at the snow-atmosphere interface. An inspection of this widely used equation reveals that the areal units for three of the energy fluxes disregard the effect of sloped terrain and as a result presents a unit inconsistency in the equation. The objectives of this paper are to: (1) introduce a corrected SST equation; (2) discuss the role of the SST in snow models; and (3) assess the impact of this unit inconsistency on the simulation of snow variables in various climatic conditions. Meteorological observations were used to compare results that were obtained by implementation of the original and the corrected SST equations in a point energy and mass balance snow model. The calculated SST values in the original equation tend to be higher than the calculated value in the corrected equation. As a result when the original equation is used the SST-dependent energy fluxes (i.e. sensible heat, latent heat and net long-wave radiation) into the snow are lower, which yield lower melting rates. In conclusion, while the original SST equation might be applicable in snow models for gentle terrain, it introduces substantial biases in steep terrain. Therefore, it is conservatively recommended to consider the implementation of the corrected SST equation for snow model applications in mountainous terrain that are steeper than 15°.",

keywords = "Energy balance, Mountainous terrain, Sloped terrain, Snow point model, Snow surface temperature, UEB",

author = "Rotem Sade and Alon Rimmer and {Iggy Litaor}, M. and Eylon Shamir and Alex Furman",

note = "Funding Information: This research was partly supported by the Israeli Water Authority, and partly by GLOWA - Jordan River Project, funded by the German Ministry of Science and Education (BMBF), in collaboration with the Israeli Ministry of Science and Technology (MOST). We also want to thank the two anonymous reviewers for their helpful and constructive feedback.",

year = "2011",

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doi = "10.1016/j.jhydrol.2011.08.001",

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AU - Sade, Rotem

AU - Rimmer, Alon

AU - Iggy Litaor, M.

AU - Shamir, Eylon

AU - Furman, Alex

N1 - Funding Information: This research was partly supported by the Israeli Water Authority, and partly by GLOWA - Jordan River Project, funded by the German Ministry of Science and Education (BMBF), in collaboration with the Israeli Ministry of Science and Technology (MOST). We also want to thank the two anonymous reviewers for their helpful and constructive feedback.

PY - 2011/10/13

Y1 - 2011/10/13

N2 - Snow surface temperature (SST) is a key component in the calculation of snow-surface energy balance. Common snow models have adapted a specific linearized SST equation that accounts for the energy fluxes at the snow-atmosphere interface. An inspection of this widely used equation reveals that the areal units for three of the energy fluxes disregard the effect of sloped terrain and as a result presents a unit inconsistency in the equation. The objectives of this paper are to: (1) introduce a corrected SST equation; (2) discuss the role of the SST in snow models; and (3) assess the impact of this unit inconsistency on the simulation of snow variables in various climatic conditions. Meteorological observations were used to compare results that were obtained by implementation of the original and the corrected SST equations in a point energy and mass balance snow model. The calculated SST values in the original equation tend to be higher than the calculated value in the corrected equation. As a result when the original equation is used the SST-dependent energy fluxes (i.e. sensible heat, latent heat and net long-wave radiation) into the snow are lower, which yield lower melting rates. In conclusion, while the original SST equation might be applicable in snow models for gentle terrain, it introduces substantial biases in steep terrain. Therefore, it is conservatively recommended to consider the implementation of the corrected SST equation for snow model applications in mountainous terrain that are steeper than 15°.

AB - Snow surface temperature (SST) is a key component in the calculation of snow-surface energy balance. Common snow models have adapted a specific linearized SST equation that accounts for the energy fluxes at the snow-atmosphere interface. An inspection of this widely used equation reveals that the areal units for three of the energy fluxes disregard the effect of sloped terrain and as a result presents a unit inconsistency in the equation. The objectives of this paper are to: (1) introduce a corrected SST equation; (2) discuss the role of the SST in snow models; and (3) assess the impact of this unit inconsistency on the simulation of snow variables in various climatic conditions. Meteorological observations were used to compare results that were obtained by implementation of the original and the corrected SST equations in a point energy and mass balance snow model. The calculated SST values in the original equation tend to be higher than the calculated value in the corrected equation. As a result when the original equation is used the SST-dependent energy fluxes (i.e. sensible heat, latent heat and net long-wave radiation) into the snow are lower, which yield lower melting rates. In conclusion, while the original SST equation might be applicable in snow models for gentle terrain, it introduces substantial biases in steep terrain. Therefore, it is conservatively recommended to consider the implementation of the corrected SST equation for snow model applications in mountainous terrain that are steeper than 15°.

KW - Energy balance

KW - Mountainous terrain

KW - Sloped terrain

KW - Snow point model

KW - Snow surface temperature

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JO - Journal of Hydrology

JF - Journal of Hydrology

IS - 3-4

ER -

The sensitivity of snow-surface temperature equation to sloped terrain

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Keywords

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