Micrometeorological and morphological observations of surface hoar dynamics on a mountain snow cover
Micrometeorological and morphological observations of surface hoar dynamics on a mountain snow cover
The formation, growth, and destruction of surface hoar crystals is an important feature of mountain snow covers as buried surface hoar layers are a frequent weak layer leading to unstable snowpacks. The energy and mass exchange associated with surface hoar dynamics is further an important part of land-atmosphere interaction over snow. A quantitative prediction of surface hoar evolution based on local environmental conditions is, however, difficult. We carried out measurements of crystal hoar size and total surface mass changes in the period between January and March 2007 on the Weissfluhjoch study plot of the WSL Institute for Snow and Avalanche Research SLF, located above Davos, Switzerland, at 2540 m above sea level. For the first time, a direct comparison between eddy correlation measurements of latent heat flux and lysimeter-like measurements of surface mass change has been made. Results show that the growth of surface hoar crystals is very well correlated with deposition of water vapor during clear-sky nights as measured by two eddy correlation systems placed close to the ground. By analyzing local meteorological data, we confirm that low to moderate wind speed, humid air, and clear-sky nights are the necessary ingredients for the occurrence of significant vapor fluxes toward the surface and thus for the growth of surface hoar. We also confirm that surface hoar crystals tend to preserve during daytime, when strong sublimation occurs, although their size significantly reduces. Despite the complexities associated with mountain terrain and snow surfaces, such as nonequilibrium boundary layers and stratification effects, the hoar formation could be predicted by the snow cover model SNOWPACK, which uses a bulk Monin-Obukhov (MO) parameterization for the turbulent heat fluxes. On the basis of the comparison between direct observations and model predictions, we suggest that neutral stability conditions in the MO formulation provide the most stable and least flawed prediction for surface hoar formation
W04511-[11pp}
Stossel, F.
4a8cda07-e417-45c1-aa14-0040bd1ebc05
Guala, M.
f5c0d890-4ebc-419e-8fad-00f765277195
Fierz, C.
2e2d1604-ae17-4a17-b37f-a8a3d2fd99ec
Manes, C.
7d9d5123-4d1b-4760-beff-d82fe0bd0acf
Lehning, M.
72ba397f-301c-476f-83b0-d37f7620731e
24 April 2010
Stossel, F.
4a8cda07-e417-45c1-aa14-0040bd1ebc05
Guala, M.
f5c0d890-4ebc-419e-8fad-00f765277195
Fierz, C.
2e2d1604-ae17-4a17-b37f-a8a3d2fd99ec
Manes, C.
7d9d5123-4d1b-4760-beff-d82fe0bd0acf
Lehning, M.
72ba397f-301c-476f-83b0-d37f7620731e
Stossel, F., Guala, M., Fierz, C., Manes, C. and Lehning, M.
(2010)
Micrometeorological and morphological observations of surface hoar dynamics on a mountain snow cover.
Water Resources Research, 46 (4), .
(doi:10.1029/2009WR008198).
Abstract
The formation, growth, and destruction of surface hoar crystals is an important feature of mountain snow covers as buried surface hoar layers are a frequent weak layer leading to unstable snowpacks. The energy and mass exchange associated with surface hoar dynamics is further an important part of land-atmosphere interaction over snow. A quantitative prediction of surface hoar evolution based on local environmental conditions is, however, difficult. We carried out measurements of crystal hoar size and total surface mass changes in the period between January and March 2007 on the Weissfluhjoch study plot of the WSL Institute for Snow and Avalanche Research SLF, located above Davos, Switzerland, at 2540 m above sea level. For the first time, a direct comparison between eddy correlation measurements of latent heat flux and lysimeter-like measurements of surface mass change has been made. Results show that the growth of surface hoar crystals is very well correlated with deposition of water vapor during clear-sky nights as measured by two eddy correlation systems placed close to the ground. By analyzing local meteorological data, we confirm that low to moderate wind speed, humid air, and clear-sky nights are the necessary ingredients for the occurrence of significant vapor fluxes toward the surface and thus for the growth of surface hoar. We also confirm that surface hoar crystals tend to preserve during daytime, when strong sublimation occurs, although their size significantly reduces. Despite the complexities associated with mountain terrain and snow surfaces, such as nonequilibrium boundary layers and stratification effects, the hoar formation could be predicted by the snow cover model SNOWPACK, which uses a bulk Monin-Obukhov (MO) parameterization for the turbulent heat fluxes. On the basis of the comparison between direct observations and model predictions, we suggest that neutral stability conditions in the MO formulation provide the most stable and least flawed prediction for surface hoar formation
Text
Stossel_et_al_2010.pdf
- Version of Record
More information
Published date: 24 April 2010
Organisations:
Energy & Climate Change Group
Identifiers
Local EPrints ID: 204115
URI: http://eprints.soton.ac.uk/id/eprint/204115
ISSN: 0043-1397
PURE UUID: c7808cd6-ad1f-42a7-8d51-fadc5907135b
Catalogue record
Date deposited: 24 Nov 2011 12:23
Last modified: 14 Mar 2024 04:30
Export record
Altmetrics
Contributors
Author:
F. Stossel
Author:
M. Guala
Author:
C. Fierz
Author:
C. Manes
Author:
M. Lehning
Download statistics
Downloads from ePrints over the past year. Other digital versions may also be available to download e.g. from the publisher's website.
View more statistics