Modelled sensitivity of the snow regime to topography, shrub fraction and shrub height

Ménard, Cécile B.; Essery, Richard; Pomeroy, John W.

doi:10.5194/hess-18-2375-2014

Cited by 43 publications

(61 citation statements)

References 68 publications

(104 reference statements)

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“…Liston (2004) improved a regional climate model by performing separate surface energy balance calculations over snow-covered and snow-free fractions of each model grid cell. Similar, Ménard et al (2014) calculated vertical and horizontal energy fluxes between the atmosphere and snow, snow-free and vegetation grid cell portions and found a warming feedback through decreases in surface albedo and increases in sensible heat fluxes to the atmosphere. Liston (2004) computed SCAs by assuming lognormally distributed snow depth and by introducing a dichotomous key for coefficient of variations for snow depth (CV is standard deviation divided by mean) depending on topographic variability, air temperature and wind speed.…”

Section: Introductionmentioning

confidence: 54%

Fractional snow-covered area parameterization over complex topography

Helbig¹,

Herwijnen²,

Magnusson³

et al. 2015

Hydrol. Earth Syst. Sci.

118

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Abstract. Fractional snow-covered area (SCA) is a key parameter in large-scale hydrological, meteorological and regional climate models. Since SCA affects albedos and surface energy balance fluxes, it is especially of interest over mountainous terrain where generally a reduced SCA is observed in large grid cells. Temporal and spatial snow distributions are, however, difficult to measure over complex topography. We therefore present a parameterization of SCA based on a new subgrid parameterization for the standard deviation of snow depth over complex topography. Highly resolved snow depth data at the peak of winter were used from two distinct climatic regions, in eastern Switzerland and in the Spanish Pyrenees. Topographic scaling parameters are derived assuming Gaussian slope characteristics. We use computationally cheap terrain parameters, namely, the correlation length of subgrid topographic features and the mean squared slope. A scale dependent analysis was performed by randomly aggregating the alpine catchments in domain sizes ranging from 50 m to 3 km. For the larger domain sizes, snow depth was predominantly normally distributed. Trends between terrain parameters and standard deviation of snow depth were similar for both climatic regions, allowing one to parameterize the standard deviation of snow depth based on terrain parameters. To make the parameterization widely applicable, we introduced the mean snow depth as a climate indicator. Assuming a normal snow distribution and spatially homogeneous melt, snow-cover depletion (SCD) curves were derived for a broad range of coefficients of variations. The most accurate closed form fit resembled an existing fractional SCA parameterization. By including the subgrid parameterization for the standard deviation of snow depth, we extended the fractional SCA parameterization for topographic influences.For all domain sizes we obtained errors lower than 10 % between measured and parameterized SCA.

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Section: Introductionmentioning

confidence: 54%

Fractional snow-covered area parameterization over complex topography

Helbig¹,

Herwijnen²,

Magnusson³

et al. 2015

Hydrol. Earth Syst. Sci.

118

View full text Add to dashboard Cite

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“…The soil routine is described in Ménard et al . (). Meteorological observations other than wind speed and slope‐projected shortwave radiation were assumed to be homogeneous.…”

Section: Methodsmentioning

confidence: 99%

“…() and Ménard et al . () have shown that variable wind exposure over complex terrain strongly influences turbulent transfer to snow and subsequent melt rates.…”

Section: Introductionmentioning

confidence: 99%

Impact of windflow calculations on simulations of alpine snow accumulation, redistribution and ablation

Musselman

Pomeroy

Essery

et al. 2015

Hydrological Processes

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“…Snow‐covered area declines, and snow cover becomes patchy during the course of snow ablation, significantly influencing snow‐atmosphere interactions and snowmelt rates (Granger et al, ; Marsh & Pomeroy , ; Ménard et al , ; Pomeroy et al, ). The differences in energetics across snow and nonsnow areas lead to a heterogeneous distribution of surface temperatures as snow is limited to a maximum of 0°C due to phase change.…”

Section: Introductionmentioning

confidence: 99%

Local‐Scale Advection of Sensible and Latent Heat During Snowmelt

Harder

Pomeroy

Helgason

2017

Geophysical Research Letters

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The breakup of snow cover into patches during snowmelt leads to a dynamic, heterogeneous land surface composed of melting snow, and wet and dry soil and plant surfaces. Energy exchange with the atmosphere is therefore complicated by horizontal gradients in surface temperature and humidity as snow surface temperature and humidity are regulated by the phase change of melting snow unlike snow‐free areas. Airflow across these surface transitions results in local‐scale advection of energy that has been documented as sensible heat during snowmelt, while latent heat advection has received scant attention. Herein, results are presented from an experiment measuring near‐surface profiles of air temperature and humidity across snow‐free to snow‐covered transitions that demonstrates that latent heat advection can be the same order of magnitude as sensible heat advection and is therefore an important source of snowmelt energy. Latent heat advection is conditional on an upwind source of water vapor from a wetted snow‐free surface.

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Modelled sensitivity of the snow regime to topography, shrub fraction and shrub height

Cited by 43 publications

References 68 publications

Fractional snow-covered area parameterization over complex topography

Fractional snow-covered area parameterization over complex topography

Impact of windflow calculations on simulations of alpine snow accumulation, redistribution and ablation

Local‐Scale Advection of Sensible and Latent Heat During Snowmelt

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