Implementation of a physically based water percolation routine in the Crocus/SURFEX (V7.3) snowpack model
We present a new water percolation routine added to the one-dimensional snowpack model Crocus as an alternative to the empirical bucket routine. This routine solves the Richards equation, which describes flow of water through unsaturated porous snow governed by capillary suction, gravity and hydr...
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Copernicus Publications
2017-09-01
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| Series: | Geoscientific Model Development |
| Online Access: | https://www.geosci-model-dev.net/10/3547/2017/gmd-10-3547-2017.pdf |
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doaj-0f57257f803942b89f7adcc2e30e33392020-11-25T00:14:45ZengCopernicus PublicationsGeoscientific Model Development1991-959X1991-96032017-09-01103547356610.5194/gmd-10-3547-2017Implementation of a physically based water percolation routine in the Crocus/SURFEX (V7.3) snowpack modelC. J. L. D'Amboise0C. J. L. D'Amboise1K. Müller2L. Oxarango3S. Morin4T. V. Schuler5Norwegian Water Resources and Energy Directorate, Oslo, 0368, NorwayDepartment of Geoscience, University of Oslo, Oslo, 0316, NorwayNorwegian Water Resources and Energy Directorate, Oslo, 0368, NorwayUniv. Grenoble Alpes, CNRS, IRD, IGE, 38000 Grenoble, FranceMétéo-France – CNRS, CNRM UMR 3589, Centre d'Etudes de la Neige, Grenoble, FranceDepartment of Geoscience, University of Oslo, Oslo, 0316, NorwayWe present a new water percolation routine added to the one-dimensional snowpack model Crocus as an alternative to the empirical bucket routine. This routine solves the Richards equation, which describes flow of water through unsaturated porous snow governed by capillary suction, gravity and hydraulic conductivity of the snow layers. We tested the Richards routine on two data sets, one recorded from an automatic weather station over the winter of 2013–2014 at Filefjell, Norway, and the other an idealized synthetic data set. Model results using the Richards routine generally lead to higher water contents in the snow layers. Snow layers often reached a point at which the ice crystals' surface area is completely covered by a thin film of water (the transition between pendular and funicular regimes), at which feedback from the snow metamorphism and compaction routines are expected to be nonlinear. With the synthetic simulation 18 % of snow layers obtained a saturation of > 10 % and 0.57 % of layers reached saturation of > 15 %. The Richards routine had a maximum liquid water content of 173.6 kg m<sup>−3</sup> whereas the bucket routine had a maximum of 42.1 kg m<sup>−3</sup>. We found that wet-snow processes, such as wet-snow metamorphism and wet-snow compaction rates, are not accurately represented at higher water contents. These routines feed back on the Richards routines, which rely heavily on grain size and snow density. The parameter sets for the water retention curve and hydraulic conductivity of snow layers, which are used in the Richards routine, do not represent all the snow types that can be found in a natural snowpack. We show that the new routine has been implemented in the Crocus model, but due to feedback amplification and parameter uncertainties, meaningful applicability is limited. Updating or adapting other routines in Crocus, specifically the snow compaction routine and the grain metamorphism routine, is needed before Crocus can accurately simulate the snowpack using the Richards routine.https://www.geosci-model-dev.net/10/3547/2017/gmd-10-3547-2017.pdf |
| collection |
DOAJ |
| language |
English |
| format |
Article |
| sources |
DOAJ |
| author |
C. J. L. D'Amboise C. J. L. D'Amboise K. Müller L. Oxarango S. Morin T. V. Schuler |
| spellingShingle |
C. J. L. D'Amboise C. J. L. D'Amboise K. Müller L. Oxarango S. Morin T. V. Schuler Implementation of a physically based water percolation routine in the Crocus/SURFEX (V7.3) snowpack model Geoscientific Model Development |
| author_facet |
C. J. L. D'Amboise C. J. L. D'Amboise K. Müller L. Oxarango S. Morin T. V. Schuler |
| author_sort |
C. J. L. D'Amboise |
| title |
Implementation of a physically based water percolation routine in the Crocus/SURFEX (V7.3) snowpack model |
| title_short |
Implementation of a physically based water percolation routine in the Crocus/SURFEX (V7.3) snowpack model |
| title_full |
Implementation of a physically based water percolation routine in the Crocus/SURFEX (V7.3) snowpack model |
| title_fullStr |
Implementation of a physically based water percolation routine in the Crocus/SURFEX (V7.3) snowpack model |
| title_full_unstemmed |
Implementation of a physically based water percolation routine in the Crocus/SURFEX (V7.3) snowpack model |
| title_sort |
implementation of a physically based water percolation routine in the crocus/surfex (v7.3) snowpack model |
| publisher |
Copernicus Publications |
| series |
Geoscientific Model Development |
| issn |
1991-959X 1991-9603 |
| publishDate |
2017-09-01 |
| description |
We present a new water percolation routine added to the one-dimensional snowpack model
Crocus as an alternative to the empirical bucket routine. This routine solves
the Richards equation, which describes flow of water through unsaturated
porous snow governed by capillary suction, gravity and hydraulic conductivity
of the snow layers. We tested the Richards routine on two data sets, one
recorded from an automatic weather station over the winter of 2013–2014 at
Filefjell, Norway, and the other an idealized synthetic data set. Model results using
the Richards routine generally lead to higher water contents in the snow
layers. Snow layers often reached a point at which the ice crystals' surface area
is completely covered by a thin film of water (the transition between
pendular and funicular regimes), at which feedback from the snow metamorphism
and compaction routines are expected to be nonlinear. With the synthetic
simulation 18 % of snow layers obtained a saturation of > 10 % and
0.57 % of layers reached saturation of > 15 %. The Richards
routine had a maximum liquid water content of 173.6 kg m<sup>−3</sup> whereas the
bucket routine had a maximum of 42.1 kg m<sup>−3</sup>. We found that wet-snow
processes, such as wet-snow metamorphism and wet-snow compaction rates, are
not accurately represented at higher water contents. These routines feed back
on the Richards routines, which rely heavily on grain size and snow density.
The parameter sets for the water retention curve and hydraulic conductivity
of snow layers, which are used in the Richards routine, do not represent all
the snow types that can be found in a natural snowpack. We show that the new
routine has been implemented in the Crocus model, but due to feedback
amplification and parameter uncertainties, meaningful applicability is
limited. Updating or adapting other routines in Crocus, specifically the snow
compaction routine and the grain metamorphism routine, is needed before
Crocus can accurately simulate the snowpack using the Richards routine. |
| url |
https://www.geosci-model-dev.net/10/3547/2017/gmd-10-3547-2017.pdf |
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