Representing spatial variability of snow water equivalent in hydrologic and land‐surface models: A review

Clark, Martyn P.; Hendrikx, Jordy; Slater, A. G.; Kavetski, Dmitri; Anderson, B.; Cullen, Nicolas J.; Kerr, Tim; Hreinsson, Einar Örn; Woods, Ross

doi:10.1029/2011wr010745

Cited by 319 publications

(410 citation statements)

References 98 publications

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“…Considerable spatial subgrid variability in SWE and SD is caused, among others, by local precipitation patterns and by wind redistribution of snow, which again is dependent on the type of vegetation and topography (e.g. Armstrong and Brun, 2008;Clark et al, 2011). As an example of the observational uncertainty, the high-resolution SD measurements across the Hardangervidda mountain plateau (Ragulina et al, 2011;see Sect.…”

Section: Discussionmentioning

confidence: 99%

“…Secondly, there is the uncertainty connected to the rather substantial natural spatial variability in snow conditions within the model 1 × 1 km grid-cells (see e.g. Clark et al, 2011), and to how well the point-and snow course-based measurements can capture this variability. Finally, there is also the uncertainty connected to the snow observations, although this uncertainty is often relatively small when compared to the spatial variability, for example (except for density, which can sometimes be demanding to measure).…”

Section: Discussionmentioning

confidence: 99%

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Simulating snow maps for Norway: description and statistical evaluation of the seNorge snow model

Saloranta

2012

The Cryosphere

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Abstract. Daily maps of snow conditions have been produced in Norway with the seNorge snow model since 2004. The seNorge snow model operates with 1 × 1 km resolution, uses gridded observations of daily temperature and precipitation as its input forcing, and simulates, among others, snow water equivalent (SWE), snow depth (SD), and the snow bulk density (ρ). In this paper the set of equations contained in the seNorge model code is described and a thorough spatiotemporal statistical evaluation of the model performance from 1957-2011 is made using the two major sets of extensive in situ snow measurements that exist for Norway. The evaluation results show that the seNorge model generally overestimates both SWE and ρ, and that the overestimation of SWE increases with elevation throughout the snow season. However, the R 2 -values for model fit are 0.60 for (logtransformed) SWE and 0.45 for ρ, indicating that after removal of the detected systematic model biases (e.g. by recalibrating the model or expressing snow conditions in relative units) the model performs rather well. The seNorge model provides a relatively simple, not very data-demanding, yet nonetheless process-based method to construct snow maps of high spatiotemporal resolution. It is an especially well suited alternative for operational snow mapping in regions with rugged topography and large spatiotemporal variability in snow conditions, as is the case in the mountainous Norway.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Simulating snow maps for Norway: description and statistical evaluation of the seNorge snow model

Saloranta

2012

The Cryosphere

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“…Understanding the snow cover distribution is important to improve prediction of snow related disasters. The primary factors that affect snow cover distribution are related to the horizontal scale (Seyfried and Wilcox 1995;Clark et al 2011). The predominant elements of snow cover depend on the horizontal scale, surface roughness and presence of an individual tree or shrub on a point scale, effects of drifting and avalanching on a hillslope scale (0.001−0.1 km), freezing level and melt energy on a watershed scale (0.1−10 km), and horizontal precipitation gradients on a regional scale (10−1000 km).…”

Section: Introductionmentioning

confidence: 99%

Analysis of Regional Difference in Altitude Dependence of Snow Depth Using High Resolve Numerical Experiments

Uno

Kawase

Ishizaki

et al. 2014

SOLA

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This study focuses on the main factor of regional difference in Altitudinal Dependency of Snow Depth (ADSD) and discusses the applicable range of snow cover estimation method with ADSD. We use the high-density surface observational data and a regional climate model in Niigata Prefecture. The estimation method with ADSD produces significant estimation error if the method is applied to broad areas. The high-density observational data show the regional difference of ADSD between windward and leeward areas with a coastal mountain. Numerical simulation reproduces these observational results. We evaluate mountain effects on the regional difference of ADSD using sensitivity experiments. In the sensitivity experiment, the altitude is changed from a mountain to a flat plain. The sensitivity experiment shows that the regional differences of ADSD are not simulated. The results indicate that the applicable range of the estimation method with ADSD is limited to a single slope and mountain. It should be noted that this method has a high probability of increasing the estimation error in

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“…Such controls of water table depth on runoff production and evapotranspiration on catchment scales represent just one hypothesis of similarity and scaling behavior -an example alternative hypothesis, used in the variable infiltration capacity (VIC) model (Liang et al, 1994), is the description of how subelement variability in soil moisture affects the development of saturated areas in a catchment and the partitioning of precipitation into surface runoff and infiltration (Moore and Clarke, 1981;Dümenil and Todini, 1992;Wood et al, 1992;Hagemann and Gates, 2003). Other scaling hypotheses are used for other physical processes, for example, how small-scale variability in snow affects large-scale snow melt (Luce et al, 1999;Liston, 2004;Clark et al, 2011a) and how energy fluxes for individual leaves scale up to the vegetation canopy (de Pury and Farquar, 1997;Wang and Leuning, 1998).…”

Section: Scaling and Similarity Hypothesesmentioning

confidence: 99%

Scaling, similarity, and the fourth paradigm for hydrology

Peters‐Lidard

Clark

Samaniego

et al. 2017

Hydrol. Earth Syst. Sci.

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Abstract. In this synthesis paper addressing hydrologic scaling and similarity, we posit that roadblocks in the search for universal laws of hydrology are hindered by our focus on computational simulation (the third paradigm) and assert that it is time for hydrology to embrace a fourth paradigm of dataintensive science. Advances in information-based hydrologic science, coupled with an explosion of hydrologic data and advances in parameter estimation and modeling, have laid the foundation for a data-driven framework for scrutinizing hydrological scaling and similarity hypotheses. We summarize important scaling and similarity concepts (hypotheses) that require testing; describe a mutual information framework for testing these hypotheses; describe boundary condition, state, flux, and parameter data requirements across scales to support testing these hypotheses; and discuss some challenges to overcome while pursuing the fourth hydrological paradigm. We call upon the hydrologic sciences community to develop a focused effort towards adopting the fourth paradigm and apply this to outstanding challenges in scaling and similarity.

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Representing spatial variability of snow water equivalent in hydrologic and land‐surface models: A review

Cited by 319 publications

References 98 publications

Simulating snow maps for Norway: description and statistical evaluation of the seNorge snow model

Simulating snow maps for Norway: description and statistical evaluation of the seNorge snow model

Analysis of Regional Difference in Altitude Dependence of Snow Depth Using High Resolve Numerical Experiments

Scaling, similarity, and the fourth paradigm for hydrology

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