A new fractional snow-covered area parameterization for the Community Land Model and its effect on the surface energy balance

One function of the Community Land Model (CLM4) is the determination of surface albedo in the Community Earth System Model (CESM1). Because the typical spatial scales of CESM1 simulations are large compared to the scales of variability of surface properties such as snow cover and vegetation, unresol...

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Bibliographic Details
Published in:Journal of Geophysical Research: Atmospheres 2012-11, Vol.117 (D21), p.n/a
Main Authors: Swenson, S. C., Lawrence, D. M.
Format: Article
Language:English
Subjects:
Albedo
CESM
Climate change
Climatology. Bioclimatology. Climate change
CLM
Cryosphere
Earth
Earth, ocean, space
Energy balance
Exact sciences and technology
External geophysics
Free surfaces
Geophysics
Geophysics. Techniques, methods, instrumentation and models
Heterogeneity
Hydrology
Ice
Meteorology
Snow
Snow accumulation
Snow cover
Snow density
Snow depth
Snow-water equivalent
Snow. Ice. Glaciers
Soil temperature
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Summary:One function of the Community Land Model (CLM4) is the determination of surface albedo in the Community Earth System Model (CESM1). Because the typical spatial scales of CESM1 simulations are large compared to the scales of variability of surface properties such as snow cover and vegetation, unresolved surface heterogeneity is parameterized. Fractional snow‐covered area, or snow‐covered fraction (SCF), within a CLM4 grid cell is parameterized as a function of grid cell mean snow depth and snow density. This parameterization is based on an analysis of monthly averaged SCF and snow depth that showed a seasonal shift in the snow depth–SCF relationship. In this paper, we show that this shift is an artifact of the monthly sampling and that the current parameterization does not reflect the relationship observed between snow depth and SCF at the daily time scale. We demonstrate that the snow depth analysis used in the original study exhibits a bias toward early melt when compared to satellite‐observed SCF. This bias results in a tendency to overestimate SCF as a function of snow depth. Using a more consistent, higher spatial and temporal resolution snow depth analysis reveals a clear hysteresis between snow accumulation and melt seasons. Here, a new SCF parameterization based on snow water equivalent is developed to capture the observed seasonal snow depth–SCF evolution. The effects of the new SCF parameterization on the surface energy budget are described. In CLM4, surface energy fluxes are calculated assuming a uniform snow cover. To more realistically simulate environments having patchy snow cover, we modify the model by computing the surface fluxes separately for snow‐free and snow‐covered fractions of a grid cell. In this configuration, the form of the parameterized snow depth–SCF relationship is shown to greatly affect the surface energy budget. The direct exposure of the snow‐free surfaces to the atmosphere leads to greater heat loss from the ground during autumn and greater heat gain during spring. The net effect is to reduce annual mean soil temperatures by up to 3°C in snow‐affected regions. Key Points Current CLM snow cover fraction (SCF) is biased New data better constrain SCF New parameterization impacts surface energy balance
ISSN:0148-0227
2169-897X
2156-2202
2169-8996
DOI:10.1029/2012JD018178