A catchment‐based approach to modeling land surface processes in a general circulation model: 1. Model structure

Koster, Randal D.; Suárez, Max J.; Ducharne, Agnès; Stieglitz, Marc; Kumar, Praveen

doi:10.1029/2000jd900327

Cited by 726 publications

(530 citation statements)

References 40 publications

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“…The multilayer, physically based snow scheme included in the CLSM (Lynch-Stieglitz 1994)i so fi n t e r m e d i a t e complexity according to Boone and Etchevers's (2001) classification of snow schemes and has shown good performance in different studies (Stieglitz et al 2001;Gascoin et al 2009b;Koster et al 2010). The snow model vertically discretizes the snowpack into three layers, and each of them is characterized by its heat content, SWE, and snow depth (Lynch-Stieglitz 1994;Stieglitz et al 2001;D ery et al 2004).…”

Section: Initial Snow-cover Parameterizationmentioning

confidence: 99%

“…The Catchment land surface model (CLSM) is an LSM developed by Koster et al (2000) and Ducharne et al (2000) to generate water and energy fluxes between land surfaces and the atmosphere in general circulation models (GCMs) in which a multilayer, physically based snow scheme is included (Lynch-Stieglitz 1994). We applied this model in the Durance watershed (approximately 14 000 km 2 ) located in the southern French Alps with an altitude range of 4000 m (see Fig.…”

Section: Introductionmentioning

confidence: 99%

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Introducing Hysteresis in Snow Depletion Curves to Improve the Water Budget of a Land Surface Model in an Alpine Catchment

Magand

Ducharne

Moine

et al. 2014

Journal of Hydrometeorology

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To cite this version:Claire Magand, Agnès Ducharne, Nicolas Le Moine, Simon Gascoin. Introducing hysteresis in snow depletion curves to improve the water budget of a land surface model in an Alpine catchment. Journal of Hydrometeorology, American Meteorological Society, 2014, 15 (2) ), located in the French Alps, generates 10% of French hydropower and provides drinking water to 3 million people. The Catchment land surface model (CLSM), a distributed land surface model (LSM) with a multilayer, physically based snow model, has been applied in the upstream part of this watershed, where snowfall accounts for 50% of the precipitation. The CLSM subdivides the upper Durance watershed, where elevations range from 800 to 4000 m within 3580 km 2 , into elementary catchments with an average area of 500 km 2 . The authors first show the difference between the dynamics of the accumulation and ablation of the snow cover using Moderate Resolution Imaging Spectroradiometer (MODIS) images and snow-depth measurements. The extent of snow cover increases faster during accumulation than during ablation because melting occurs at preferential locations. This difference corresponds to the presence of a hysteresis in the snow-cover depletion curve of these catchments, and the CLSM was adapted by implementing such a hysteresis in the snow-cover depletion curve of the model. Different simulations were performed to assess the influence of the parameterizations on the water budget and the evolution of the extent of the snow cover. Using six gauging stations, the authors demonstrate that introducing a hysteresis in the snow-cover depletion curve improves melting dynamics. They conclude that their adaptation of the CLSM contributes to a better representation of snowpack dynamics in an LSM that enables mountainous catchments to be modeled for impact studies such as those of climate change.

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Section: Initial Snow-cover Parameterizationmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Introducing Hysteresis in Snow Depletion Curves to Improve the Water Budget of a Land Surface Model in an Alpine Catchment

Magand

Ducharne

Moine

et al. 2014

Journal of Hydrometeorology

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“…In contrast to the traditional gridded delineation, CLSM divides areas into irregularly shaped topographic catchments, which each contain a saturated fraction, a sub-saturated fraction, and a wilting fraction. These fractions evolve over time, and are used to determine fluxes and soil states within the catchment [more details can be found in Koster et al, 2000;Reichle et al, 2011;Houborg et al, 2012]. The soil profile depths were compiled from the FAO/ UNESCO Soil Map of the World (Webb et al, 1991).…”

Section: Land Surface Modelsmentioning

confidence: 99%

Upper Blue Nile basin water budget from a multi-model perspective

Jung

Getirana

Policelli

et al. 2017

Journal of Hydrology

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a b s t r a c tImproved understanding of the water balance in the Blue Nile is of critical importance because of increasingly frequent hydroclimatic extremes under a changing climate. The intercomparison and evaluation of multiple land surface models (LSMs) associated with different meteorological forcing and precipitation datasets can offer a moderate range of water budget variable estimates. In this context, two LSMs, Noah version 3.3 (Noah3.3) and Catchment LSM version Fortuna 2.5 (CLSMF2.5) coupled with the Hydrological Modeling and Analysis Platform (HyMAP) river routing scheme are used to produce hydrological estimates over the region. The two LSMs were forced with different combinations of two reanalysis-based meteorological datasets from the Modern-Era Retrospective analysis for Research and Applications datasets (i.e., MERRA-Land and MERRA-2) and three observation-based precipitation datasets, generating a total of 16 experiments. Modeled evapotranspiration (ET), streamflow, and terrestrial water storage estimates were evaluated against the Atmosphere-Land Exchange Inverse (ALEXI) ET, insitu streamflow observations, and NASA Gravity Recovery and Climate Experiment (GRACE) products, respectively. Results show that CLSMF2.5 provided better representation of the water budget variables than Noah3.3 in terms of Nash-Sutcliffe coefficient when considering all meteorological forcing datasets and precipitation datasets. The model experiments forced with observation-based products, the Climate Hazards group Infrared Precipitation with Stations (CHIRPS) and the Tropical Rainfall Measuring Mission (TRMM) Multi-Satellite Precipitation Analysis (TMPA), outperform those run with MERRA-Land and MERRA-2 precipitation. The results presented in this paper would suggest that the Famine Early Warning Systems Network (FEWS NET) Land Data Assimilation System incorporate CLSMF2.5 and HyMAP routing scheme to better represent the water balance in this region.

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“…Several Land Surface Models (LSMs) (e.g. SAC-SMA (Burnash et al, 1973;Burnash, 1995;SSiB, Xue et al, 1991); Mosaic (Koster and Suarez, 1996); NSSIP (Koster et al, 2000); Variable Infiltration Capacity (VIC; Liang et al, 1994); Noah (Ek et al, 2003;Niu et al, 2011); and CLM (Bonan et al, 2012(Bonan et al, , 2011) have been developed over the last few decades to better represent land surface and atmospheric processes as well as improve estimates of various water, energy and carbon fluxes at the land surface. These models could be a valuable tool for estimating current and future recharge estimates due to projected climate change.…”

Section: Introductionmentioning

confidence: 99%

Comparing potential recharge estimates from three Land Surface Models across the western US

Niraula

Meixner

Ajami

et al. 2017

Journal of Hydrology

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a b s t r a c tGroundwater is a major source of water in the western US. However, there are limited recharge estimates in this region due to the complexity of recharge processes and the challenge of direct observations. Land surface Models (LSMs) could be a valuable tool for estimating current recharge and projecting changes due to future climate change. In this study, simulations of three LSMs (Noah, Mosaic and VIC) obtained from the North American Land Data Assimilation System (NLDAS-2) are used to estimate potential recharge in the western US. Modeled recharge was compared with published recharge estimates for several aquifers in the region. Annual recharge to precipitation ratios across the study basins varied from 0.01% to 15% for Mosaic, 3.2% to 42% for Noah, and 6.7% to 31.8% for VIC simulations. Mosaic consistently underestimates recharge across all basins. Noah captures recharge reasonably well in wetter basins, but overestimates it in drier basins. VIC slightly overestimates recharge in drier basins and slightly underestimates it for wetter basins. While the average annual recharge values vary among the models, the models were consistent in identifying high and low recharge areas in the region. Models agree in seasonality of recharge occurring dominantly during the spring across the region. Overall, our results highlight that LSMs have the potential to capture the spatial and temporal patterns as well as seasonality of recharge at large scales. Therefore, LSMs (specifically VIC and Noah) can be used as a tool for estimating future recharge in data limited regions.

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A catchment‐based approach to modeling land surface processes in a general circulation model: 1. Model structure

Cited by 726 publications

References 40 publications

Introducing Hysteresis in Snow Depletion Curves to Improve the Water Budget of a Land Surface Model in an Alpine Catchment

Introducing Hysteresis in Snow Depletion Curves to Improve the Water Budget of a Land Surface Model in an Alpine Catchment

Upper Blue Nile basin water budget from a multi-model perspective

Comparing potential recharge estimates from three Land Surface Models across the western US

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