Snow water equivalent in the Sierra Nevada: Blending snow sensor observations with snowmelt model simulations

[1] We estimate the spatial distribution of daily melt-season snow water equivalent (SWE) over the Sierra Nevada for March to August, 2000–2012, by two methods: reconstruction by combining remotely sensed snow cover images with a spatially distributed snowmelt model and a blended method in which the reconstruction is combined with in situ snow sensor observations. We validate the methods with 17 snow surveys at six locations with spatial sampling and with the operational snow sensor network. We also compare the methods with NOAA's operational Snow Data Assimilation System (SNODAS). Mean biases of the methods compared to the snow surveys are −0.193 m (reconstruction), 0.001 m (blended), and −0.181 m (SNODAS). Corresponding root-mean-square errors are 0.252, 0.205, and 0.254 m. Comparison between blended and snow sensor SWE suggests that the current sensor network inadequately represents SWE in the Sierra Nevada because of the low spatial density of sensors in the lower/higher elevations. Mean correlation with streamflow in 19 Sierra Nevada watersheds is better with reconstructed SWE (r = 0.91) versus blended SWE (r = 0.81), snow sensor SWE (r = 0.85), and SNODAS SWE (r = 0.86). On the other hand, the correlation with blended SWE is generally better than with reconstructed, snow sensor, and SNODAS SWE late in the snowmelt season when snow sensors report zero SWE but snow remains in the higher elevations. Sensitivity tests indicate downwelling longwave radiation, snow albedo, forest density, and turbulent fluxes are potentially important sources of errors/uncertainties in reconstructed SWE, and domain-mean blended SWE is relatively insensitive to the number of snow sensors blended.

[1]  D. Lettenmaier,et al.  The Effects of Climate Change on the Hydrology and Water Resources of the Colorado River Basin , 2004 .

[2]  Thomas H. Painter,et al.  Assessment of methods for mapping snow cover from MODIS , 2011 .

[3]  Kelly Elder,et al.  Snow accumulation and distribution in an Alpine Watershed , 1991 .

[4]  Lifeng Luo,et al.  Snow process modeling in the north american Land Data Assimilation System (NLDAS): 2. Evaluation of model simulated snow water equivalent : GEWEX Continental-Scale International Project, Part 3 (GCIP3) , 2003 .

[5]  Roger C. Bales,et al.  Scaling snow observations from the point to the grid element: Implications for observation network design , 2005 .

[6]  Jessica D. Lundquist,et al.  Ground-based testing of MODIS fractional snow cover in subalpine meadows and forests of the Sierra Nevada , 2013 .

[7]  Thomas R. Carroll,et al.  NOHRSC OPERATIONS AND THE SIMULATION OF SNOW COVER PROPERTIES FOR THE COTERMINOUS U.S , 2001 .

[8]  Govindasamy Bala,et al.  Evaluation of a WRF dynamical downscaling simulation over California , 2008 .

[9]  Lifeng Luo,et al.  Snow process modeling in the North American Land Data Assimilation System (NLDAS): 1. Evaluation of model‐simulated snow cover extent , 2003 .

[10]  Noel A Cressie,et al.  A comparison of geostatistical methodologies used to estimate snow water equivalent , 1996 .

[11]  E. Maurer Uncertainty in hydrologic impacts of climate change in the Sierra Nevada, California, under two emissions scenarios , 2007 .

[12]  Thomas H. Painter,et al.  Retrieval of subpixel snow covered area, grain size, and albedo from MODIS , 2009 .

[13]  Jessica D. Lundquist,et al.  Comparing and combining SWE estimates from the SNOW‐17 model using PRISM and SWE reconstruction , 2012 .

[14]  Thomas H. Painter,et al.  MULTISPECTRAL AND HYPERSPECTRAL REMOTE SENSING OF ALPINE SNOW PROPERTIES , 2004 .

[15]  D. Lettenmaier,et al.  Assimilating remotely sensed snow observations into a macroscale hydrology model , 2006 .

[16]  Christina L. Tague,et al.  APPLICATION OF THE RHESSys MODEL TO A CALIFORNIA SEMIARID SHRUBLAND WATERSHED 1 , 2004 .

[17]  T. Oki,et al.  Multimodel Estimate of the Global Terrestrial Water Balance: Setup and First Results , 2011 .

[18]  Jeff Dozier,et al.  Evaluation of distributed hydrologic impacts of temperature-index and energy-based snow models , 2013 .

[19]  Thomas A. Hennig,et al.  The Shuttle Radar Topography Mission , 2001, Digital Earth Moving.

[20]  Jeff Dozier,et al.  Estimating the spatial distribution of snow in mountain basins using remote sensing and energy balance modeling , 1998 .

[21]  Steven A. Margulis,et al.  A Bayesian approach to snow water equivalent reconstruction , 2008 .

[22]  A. Barrett,et al.  National Operational Hydrologic Remote Sensing Center SNOw Data Assimilation System (SNODAS) Products at NSIDC , 2003 .

[23]  E. Vermote,et al.  Validation of a vector version of the 6S radiative transfer code for atmospheric correction of satellite data. Part I: path radiance. , 2006, Applied optics.

[24]  D. Lettenmaier,et al.  Effects of land‐cover changes on the hydrological response of interior Columbia River basin forested catchments , 2002 .

[25]  D. L. Burge,et al.  Evaluation of Snow Water Equivalent by Airborne Measurement of Passive Terrestrial Gamma Radiation , 1971 .

[26]  Steven D. Glaser,et al.  Sensor placement strategies for snow water equivalent (SWE) estimation in the American River basin , 2013 .

[27]  R. Dickinson,et al.  One-dimensional snow water and energy balance model for vegetated surfaces , 1999 .

[28]  J. Eischeid,et al.  Constructing Retrospective Gridded Daily Precipitation and Temperature Datasets for the Conterminous United States , 2008 .

[29]  S. Warren,et al.  A Model for the Spectral Albedo of Snow. II: Snow Containing Atmospheric Aerosols , 1980 .

[30]  Martyn P. Clark,et al.  Uncertainty in seasonal snow reconstruction: Relative impacts of model forcing and image availability , 2013 .

[31]  J. Dozier,et al.  Estimating the spatial distribution of snow water equivalent in an alpine basin using binary regression tree models: the impact of digital elevation data and independent variable selection , 2005 .

[32]  F. Martin Ralph,et al.  Meteorological Characteristics and Overland Precipitation Impacts of Atmospheric Rivers Affecting the West Coast of North America Based on Eight Years of SSM/I Satellite Observations , 2008 .

[33]  Eric J. Fetzer,et al.  Extreme snowfall events linked to atmospheric rivers and surface air temperature via satellite measurements , 2010 .

[34]  Jiancheng Shi,et al.  Active Microwave Remote Sensing Systems and Applications to Snow Monitoring , 2008 .

[35]  Gerald N. Flerchinger,et al.  Comparison of algorithms for incoming atmospheric long‐wave radiation , 2009 .

[36]  Albert Rango,et al.  Areal distribution of snow water equivalent evaluated by snow cover monitoring , 1981 .

[37]  Jeff Dozier,et al.  A clear‐sky spectral solar radiation model for snow‐covered mountainous terrain , 1980 .

[38]  Timothy E. Link,et al.  Subgrid variability of snow water equivalent at operational snow stations in the western USA , 2013 .

[39]  Roger C. Bales,et al.  Snow water equivalent interpolation for the Colorado River Basin from snow telemetry (SNOTEL) data , 2003 .

[40]  Kelly Elder,et al.  Spatial Snow Modeling of Wind-Redistributed Snow Using Terrain-Based Parameters , 2002 .

[41]  J. Dozier Mountain hydrology, snow color, and the fourth paradigm , 2011 .

[42]  James S. Famiglietti,et al.  GRACE-Based Estimates of Terrestrial Freshwater Discharge from Basin to Continental Scales , 2007 .

[43]  Michael Lehning,et al.  Altitudinal dependency of snow amounts in two small alpine catchments: can catchment-wide snow amounts be estimated via single snow or precipitation stations? , 2011, Annals of Glaciology.

[44]  E. Vermote,et al.  Validation of a vector version of the 6S radiative transfer code for atmospheric correction of satellite data. Part II. Homogeneous Lambertian and anisotropic surfaces. , 2007, Applied optics.

[45]  Roger C. Bales,et al.  SNOTEL representativeness in the Rio Grande headwaters on the basis of physiographics and remotely sensed snow cover persistence , 2006 .

[46]  R. Jordan A One-dimensional temperature model for a snow cover : technical documentation for SNTHERM.89 , 1991 .

[47]  T. Erickson,et al.  Persistence of topographic controls on the spatial distribution of snow in rugged mountain terrain, Colorado, United States , 2005 .

[48]  Inference of snow cover beneath obscuring clouds using optical remote sensing and a distributed snow energy and mass balance model , 1999 .

[49]  N. Rutter,et al.  Evaluation of the NOHRSC Snow Model (NSM) in a One-Dimensional Mode , 2008 .

[50]  P. Alpert Mesoscale Indexing of the Distribution of Orographic Precipitation over High Mountains , 1986 .

[51]  D. Cayan,et al.  Precipitation structure in the Sierra Nevada of California during winter , 1999 .

[52]  Thomas H. Painter,et al.  Mountain hydrology of the western United States , 2006 .

[53]  T. Painter,et al.  Snow water equivalent along elevation gradients in the Merced and Tuolumne River basins of the Sierra Nevada , 2011 .

[54]  S. Idso A set of equations for full spectrum and 8- to 14-μm and 10.5- to 12.5-μm thermal radiation from cloudless skies , 1981 .

[55]  William P. Kustas,et al.  INCORPORATING RADIATION INPUTS INTO THE SNOWMELT RUNOFF MODEL , 1996 .

[56]  Karl Rittger,et al.  Spatial estimates of snow water equivalent in the Sierra Nevada , 2012 .

[57]  Dorothy K. Hall,et al.  An approach to using snow areal depletion curves inferred from MODIS and its application to land surface modelling in Alaska , 2005 .

[58]  Zong-Liang Yang,et al.  Retrieving snow mass from GRACE terrestrial water storage change with a land surface model , 2007 .

[59]  Thomas H. Painter,et al.  Time-space continuity of daily maps of fractional snow cover and albedo from MODIS , 2008 .

[60]  N. S. Christensen Effects of Climate Change on the Hydrology and Water Resources of the Colorado River , 2004 .

[61]  Below-surface ice melt on the coastal Antarctic ice sheet , 1999 .

[62]  Matthew Sturm,et al.  Using repeated patterns in snow distribution modeling: An Arctic example , 2010 .

[63]  J. Lundquist,et al.  Linking snowmelt‐derived fluxes and groundwater flow in a high elevation meadow system, Sierra Nevada Mountains, California , 2010 .

[64]  N. Molotch,et al.  Interannual variability of snowmelt in the Sierra Nevada and Rocky Mountains, United States: Examples from two alpine watersheds , 2012 .

[65]  Dennis P. Lettenmaier,et al.  Dynamic modeling of orographically induced precipitation , 1994 .

[66]  J. Dozier,et al.  Rapid Calculation Of Terrain Parameters For Radiation Modeling From Digital Elevation Data , 1989, 12th Canadian Symposium on Remote Sensing Geoscience and Remote Sensing Symposium,.

[67]  Kelly Elder,et al.  Comparison of spatial interpolation methods for estimating snow distribution in the Colorado Rocky Mountains , 2002 .

[68]  N. Molotch,et al.  Estimating the distribution of snow water equivalent using remotely sensed snow cover data and a spatially distributed snowmelt model: A multi-resolution, multi-sensor comparison , 2008 .

[69]  N. Molotch Reconstructing snow water equivalent in the Rio Grande headwaters using remotely sensed snow cover data and a spatially distributed snowmelt model , 2009 .

[70]  Roger C. Bales,et al.  Estimating the distribution of snow water equivalent and snow extent beneath cloud cover in the Salt–Verde River basin, Arizona , 2004 .

[71]  John S. Kimball,et al.  BIOME-BGC simulations of stand hydrologic processes for BOREAS , 1997 .