Assimilation of Satellite-Observed Snow Albedo in a Land Surface Model

Abstract This study assesses the impact of assimilating satellite-observed snow albedo on the Noah land surface model (LSM)-simulated fluxes and snow properties. A direct insertion technique is developed to assimilate snow albedo into Noah and is applied to three intensive study areas in North Park (Colorado) that are part of the 2002/03 Cold Land Processes Field Experiment (CLPX). The assimilated snow albedo products are 1) the standard Moderate Resolution Imaging Spectrometer (MODIS) product (MOD10A1) and 2) retrievals from MODIS observations with the recently developed Pattern-Based Semiempirical (PASS) approach. The performance of the Noah simulations, with and without assimilation, is evaluated using the in situ measurements of snow albedo, upward shortwave radiation, and snow depth. The results show that simulations with albedo assimilation agree better with the measurements. However, because of the limited impact of snow albedo updates after subsequent snowfall, the mean (or seasonal) error statistics decrease significantly for only two of the three CLPX sites. Though the simulated snow depth and duration for the snow season benefit from the assimilation, the greatest improvements are found in the simulated upward shortwave radiation, with root mean squared errors reduced by about 30%. As such, this study demonstrates that assimilation of satellite-observed snow albedo can improve LSM simulations, which may positively affect the representation of hydrological and surface energy budget processes in runoff and numerical weather prediction models.

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Modeling evaporation from northern waterbodies, the case of an 85-km2 reservoir

10.5194/egusphere-egu21-13049 ◽

2021 ◽

Author(s):

Habiba Kallel ◽

Murray Mackay ◽

Antoine Thiboult ◽

Daniel Nadeau ◽

François Anctil

Keyword(s):

Land Surface ◽

Weather Prediction ◽

Land Surface Model ◽

Open Water ◽

Thermal Capacity ◽

Surface Energy Budget ◽

Water Evaporation ◽

Surface Model ◽

Eastern Canada ◽

Meteorological Models

Freshwater bodies represent 9% of Canada&#8217;s total land area, with more than half of these having a surface area smaller than 100 km2. Taking into account the interactions between lakes and the atmosphere in meteorological models is crucial, considering the marked differences with the surrounding land masses (low albedo, unlimited source of water, high thermal capacity, etc.). Open water evaporation, in particular, is often a challenge because of its intangible nature and the scarcity of direct observations. This project focuses on the modeling of the surface energy budget of a reservoir located in the boreal biome of eastern Canada, with an emphasis on the evaporation. Observations are available for the 85-km2 La Romaine 2 hydroelectric reservoir (50.7&#176;N, 63.2&#176;W), where two micrometeorological towers were deployed: one operated yearlong on the shore and one operated on a floating deck during ice-free conditions. Modeling resorts to the Canadian Small Lake Model (CSLM), a one-dimensional land surface model designed to integrate the lake-atmosphere fluxes into meteorological models. The model also simulates the thermal regime of the water body, including ice formation. Lastly, the model can be used for climate and weather prediction, which may be a useful for reservoir management. Comparison of field observations and simulations confirms the CSLM ability to reproduce the turbulent fluxes and the temperature behavior of the reservoir except for some specific periods, in particular the ice breakups and freeze-ups. The model somehow underestimates the water temperature resulting in a premature depletion of the lake heat storage in autumn. It also overreacts to high wind episodes.

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Parametrizating Soil Surface Fluxes in the JULES Land Surface Model

10.5194/ismc2021-49 ◽

2021 ◽

Author(s):

John Edwards

Keyword(s):

Soil Moisture ◽

Land Surface ◽

Heat Waves ◽

Numerical Models ◽

Weather Prediction ◽

Land Surface Model ◽

Soil Surface ◽

Current Status ◽

Surface Model ◽

The Impact

The parametrization of land-atmosphere interactions in numerical weather prediction and climate models is a topic of active and growing interest, especially in connection with extreme events such as heat waves and droughts. Semiarid regions are sensitive to drought and are currently expanding, but they are often poorly represented in numerical models. On forecasting timescales, comparisons of simulated land surface temperature against retrievals from satellites often show significant cold biases around noon, whilst, on climate timescales, land surface models often fail to represent droughts realistically. Inadequate treatment of the land surface, and particularly of soil properties and soil moisture, is likely to contribute to such errors. Efforts to develop improved parametrizations of soil processes in the JULES land surface model for application in weather prediction and climate simulations are underway. Whilst processes at the soil surface are a central part of this, to obtain acceptable performance it is also important to consider the surface flux budget as a whole, including the treatment of the plant canopy. Here, we shall describe the current status of developments aimed at improving the representation of evapotranspiration and ground heat fluxes in the model, noting the major issues encountered. The importance of accurately representing the impact of soil moisture on thermal properties will be stressed. Results from initial studies will be presented and we shall offer a perspective on future developments.

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Impact of Surface Albedo Assimilation on Snow Estimation

Remote Sensing ◽

10.3390/rs12040645 ◽

2020 ◽

Vol 12 (4) ◽

pp. 645 ◽

Cited By ~ 1

Author(s):

Sujay Kumar ◽

David Mocko ◽

Carrie Vuyovich ◽

Christa Peters-Lidard

Keyword(s):

Snow Cover ◽

Land Surface ◽

Snow Depth ◽

Surface Albedo ◽

Land Surface Model ◽

Snow Accumulation ◽

High Plains ◽

Surface Model ◽

Fractional Snow Cover ◽

The Impact

Surface albedo has a significant impact in determining the amount of available net radiation at the surface and the evolution of surface water and energy budget components. The snow accumulation and timing of melt, in particular, are directly impacted by the changes in land surface albedo. This study presents an evaluation of the impact of assimilating Moderate Resolution Imaging Spectroradiometer (MODIS)-based surface albedo estimates in the Noah multi-parameterization (Noah-MP) land surface model, over the continental US during the time period from 2000 to 2017. The evaluation of simulated snow depth and snow cover fields show that significant improvements from data assimilation (DA) are obtained over the High Plains and parts of the Rocky Mountains. Earlier snowmelt and reduced agreements with reference snow depth measurements, primarily over the Northeast US, are also observed due to albedo DA. Most improvements from assimilation are observed over locations with moderate vegetation and lower elevation. The aggregate impact on evapotranspiration and runoff from assimilation is found to be marginal. This study also evaluates the relative and joint utility of assimilating fractional snow cover and surface albedo measurements. Relative to surface albedo assimilation, fractional snow cover assimilation is found to provide smaller improvements in the simulated snow depth fields. The configuration that jointly assimilates surface albedo and fractional snow cover measurements is found to provide the most beneficial improvements compared to the univariate DA configurations for surface albedo or fractional snow cover. Overall, the study also points to the need for improving the albedo formulations in land surface models and the incorporation of observational uncertainties within albedo DA configurations.

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Evaluation of the snow cover in the Soil, Vegetation, and Snow (SVS) land surface model

Journal of Hydrometeorology ◽

10.1175/jhm-d-20-0249.1 ◽

2021 ◽

Author(s):

Gonzalo Leonardini ◽

François Anctil ◽

Vincent Vionnet ◽

Maria Abrahamowicz ◽

Daniel F. Nadeau ◽

...

Keyword(s):

Snow Cover ◽

Land Surface ◽

Snow Depth ◽

Snow Water Equivalent ◽

Weather Prediction ◽

Land Surface Model ◽

Late Winter ◽

Surface Model ◽

Lower Performance ◽

Snow Water

AbstractThe Soil, Vegetation, and Snow (SVS) land surface model was recently developed at Environment and Climate Change Canada (ECCC) for operational numerical weather prediction and hydrological forecasting. This study examined the performance of the snow scheme in the SVS model over multiple years at ten well-instrumented sites from the Earth System Model-Snow Model Intercomparison Project (ESM-SnowMIP), which covers alpine, maritime and taiga climates. The SVS snow scheme is a simple single-layer snowpack scheme that uses the force-restore method. Stand-alone, point-scale verification tests showed that the model is able to realistically reproduce the main characteristics of the snow cover at these sites, namely snow water equivalent, density, snow depth, surface temperature, and albedo. SVS accurately simulated snow water equivalent, density and snow depth at open sites, but exhibited lower performance for subcanopy snowpacks (forested sites). The lower performance was attributed mainly to the limitations of the compaction scheme and the absence of a snow interception scheme. At open sites, the SVS snow surface temperatures were well represented but exhibited a cold bias, which was due to poor representation at night. SVS produced a reasonably accurate representation of snow albedo, but there was a tendency to overestimate late winter albedo. Sensitivity tests suggested improvements associated with the snow melting formulation in SVS.

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Review article: Parameterizations of snow-related physical processes in land surface models

10.5194/tc-2021-319 ◽

2021 ◽

Author(s):

Won Young Lee ◽

Hyeon-Ju Gim ◽

Seon Ki Park

Keyword(s):

Snow Cover ◽

Land Surface ◽

Snow Depth ◽

Land Surface Model ◽

Surface Model ◽

Snow Density ◽

Physical Processes ◽

Snow Albedo ◽

Surface Models ◽

Noah Land Surface Model

Abstract. Snow on land surface plays a vital role in the interaction between land and atmosphere in the state-of-the-art land surface models (LSMs) and the real world. Since the snow cover affects the snow albedo and the ground and soil heat fluxes, it is crucial to detect snow cover changes accurately. It is challenging to acquire observation data for snow cover, snow albedo, and snow depth; thus, an excellent alternative is to use the simulation data produced by the LSMs that calculate the snow-related physical processes. The LSMs show significant differences in the complexities of the snow parameterizations in terms of variables and processes considered. Thus, the synthetic intercomparisons of the snow physics in the LSMs will help the improvement of each LSM. This study revealed and discussed the differences in the parameterizations among LSMs related to snow cover fraction, snow albedo, and snow density. We selected the most popular and well-documented LSMs embedded in the Earth System Model or operational forecasting systems. We examined single layer schemes, including the Unified Noah Land Surface Model (Noah LSM), the Hydrology Tiled ECMWF Scheme of Surface Exchanges over Land (HTESSEL), the Biosphere-Atmosphere Transfer Scheme (BATS), the Canadian Land Surface Scheme (CLASS), and multilayer schemes of intermediate complexity including the Community Noah Land Surface Model with Multi-Parameterization Options (Noah-MP), the Community Land Model version 5 (CLM 5), the Joint UK Land Environment Simulator (JULES), and the Interaction Soil-Biosphere-Atmosphere (ISBA). First, we identified that BATS, Noah-MP, JULES, and ISBA reflect the snow depth and roughness length to parameterize snow cover fraction, and CLM 5 accounts for the standard deviation of the elevation value for the snow cover decay function. Second, CLM 5 and BATS are relatively complex, so that they explicitly take into account the solar zenith angle, black carbon, mineral dust, organic carbon, and ice grain size for the determinations of snow albedo. Besides, JULES and ISBA are also complicated model which concerns ice grain size, solar zenith angle, new snow depth, fresh snowfall rate, and surface temperature for the albedo scheme. Third, HTESSEL, CLM 5, and ISBA considered the effects of both wind and temperature in the determinations of the new snow density. Especially, ISBA and JULES considered internal snow characteristics such as snow viscosity, snow temperature, and vertical stress for parameterizing new snow density. The future outlook discussed geomorphic and vegetation-related variables for the further improvement of the LSMs. Previous studies clearly show that spatio-temporal variation of snow is due to the influence of altitude, slope, and vegetation condition. Therefore, we recommended applying geomorphic and vegetation factors such as elevation, slope, time-varying roughness length, vegetation indexes, or optimized parameters according to the land surface type to parameterize snow-related physical processes.

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Characterizing Surface Albedo of Shallow Fresh Snow and Its Importance for Snow Ablation on the Interior of the Tibetan Plateau

Journal of Hydrometeorology ◽

10.1175/jhm-d-19-0193.1 ◽

2020 ◽

Vol 21 (4) ◽

pp. 815-827 ◽

Cited By ~ 7

Author(s):

Wenli Wang ◽

Kun Yang ◽

Long Zhao ◽

Ziyan Zheng ◽

Hui Lu ◽

...

Keyword(s):

Tibetan Plateau ◽

Land Surface ◽

Snow Depth ◽

Surface Model ◽

Transfer Model ◽

The Tibetan Plateau ◽

Ground Truth Data ◽

Snow Albedo ◽

Fresh Snow ◽

The Impact

AbstractSnow depth on the interior of Tibetan Plateau (TP) in state-of-the-art reanalysis products is almost an order of magnitude higher than observed. This huge bias stems primarily from excessive snowfall, but inappropriate process representation of shallow snow also causes excessive snow depth and snow cover. This study investigated the issue with respect to the parameterization of fresh snow albedo. The characteristics of TP snowfall were investigated using ground truth data. Snow in the interior of the TP is usually only some centimeters in depth. The albedo of fresh snow depends on snow depth, and is frequently less than 0.4. Such low albedo values contrast with the high values (~0.8) used in the existing snow schemes of land surface models. The SNICAR radiative transfer model can reproduce the observations that fresh shallow snow has a low albedo value, based on which a fresh snow albedo scheme was derived in this study. Finally, the impact of the fresh snow albedo on snow ablation was examined at 45 meteorological stations on TP using the land surface model Noah-MP which incorporated the new scheme. Allowing albedo to change with snow depth can produce quite realistic snow depths compared with observations. In contrast, the typically assumed fresh snow albedo of 0.82 leads to too large snow depths in the snow ablation period averaged across 45 stations. The shallow snow transparency impact on snow ablation is therefore particularly important in the TP interior, where snow is rather thin and radiation is strong.

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Multiscale Evaluation of the Improvements in Surface Snow Simulation through Terrain Adjustments to Radiation

Journal of Hydrometeorology ◽

10.1175/jhm-d-12-046.1 ◽

2013 ◽

Vol 14 (1) ◽

pp. 220-232 ◽

Cited By ~ 11

Author(s):

Sujay V. Kumar ◽

Christa D. Peters-Lidard ◽

David Mocko ◽

Yudong Tian

Keyword(s):

Snow Cover ◽

Land Surface ◽

Land Surface Model ◽

Haar Wavelet ◽

Snow Accumulation ◽

Probability Of Detection ◽

Shortwave Radiation ◽

Surface Model ◽

The North ◽

The Impact

Abstract The downwelling shortwave radiation on the earth’s land surface is affected by the terrain characteristics of slope and aspect. These adjustments, in turn, impact the evolution of snow over such terrain. This article presents a multiscale evaluation of the impact of terrain-based adjustments to incident shortwave radiation on snow simulations over two midlatitude regions using two versions of the Noah land surface model (LSM). The evaluation is performed by comparing the snow cover simulations against the 500-m Moderate Resolution Imaging Spectroradiometer (MODIS) snow cover product. The model simulations are evaluated using categorical measures, such as the probability of detection of “yes” events (PODy), which measure the fraction of snow cover presence that was correctly simulated, and false alarm ratio (FAR), which measures the fraction of no-snow events that was incorrectly simulated. The results indicate that the terrain-based correction of radiation leads to systematic improvements in the snow cover estimates in both domains and in both LSM versions (with roughly 12% overall improvement in PODy and 5% improvement in FAR), with larger improvements observed during snow accumulation and melt periods. Increased contribution to PODy and FAR improvements is observed over the north- and south-facing slopes, when the overall improvements are stratified to the four cardinal aspect categories. A two-dimensional discrete Haar wavelet analysis for the two study areas indicates that the PODy improvements in snow cover estimation drop to below 10% at scales coarser than 16 km, whereas the FAR improvements are below 10% at scales coarser than 4 km.

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Effects and Sensitivity of Soot-Induced Snow Albedo Change on Snowpack

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.281.155 ◽

2011 ◽

Vol 281 ◽

pp. 155-159

Author(s):

Su Zhen Dang ◽

Chang Ming Liu

Keyword(s):

Land Surface ◽

Snow Water Equivalent ◽

Model Performance ◽

Land Surface Model ◽

Snow Accumulation ◽

Surface Model ◽

Snow Albedo ◽

Snow Water ◽

Year 2000 ◽

The Impact

The impact of soot-induced snow albedo on snow accumulation and snowpack ablation was evaluated using an energy and water balance land surface model with a newly modified snow albedo scheme. Model was tested against observed snow water equivalent (SWE) during the water year 2000 and 2002 at Ebbetts Pass site. Results show that when the soot mix ratio is 100 ng/g, the model performance is slightly improved during the snow ablation period, while snow albedo exhibits less variation. A basic sensitivity analysis indicates that snow albedo is sensitive to soot concentration in snow, and SWE is much more sensitive to soot mix ratio during the melting period, indicating the importance of accurately describing soot max ratio within snow for precisely predicting snow accumulation and snowpack ablation processes.

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Evaluation of anomalies in GLDAS-1996 dataset

Water Science & Technology ◽

10.2166/wst.2013.043 ◽

2013 ◽

Vol 67 (8) ◽

pp. 1718-1727 ◽

Cited By ~ 17

Author(s):

Xinyao Zhou ◽

Yongqiang Zhang ◽

Yonghui Yang ◽

Yanmin Yang ◽

Shumin Han

Keyword(s):

Land Surface ◽

Daily Precipitation ◽

Land Surface Model ◽

Surface Flux ◽

Shortwave Radiation ◽

Surface Model ◽

Precipitation Data ◽

Daily Precipitation Data ◽

Downward Longwave Radiation ◽

The Impact

Global Land Data Assimilation System (GLDAS) data are widely used for land-surface flux simulations. Therefore, the simulation accuracy using GLDAS dataset is largely contingent upon the accuracy of the GLDAS dataset. It is found that GLDAS land-surface model simulated runoff exhibits strong anomalies for 1996. These anomalies are investigated by evaluating four GLDAS meteorological forcing data (precipitation, air temperature, downward shortwave radiation and downward longwave radiation) in six large basins across the world (Danube, Mississippi, Yangtze, Congo, Amazon and Murray-Darling basins). Precipitation data from the Global Precipitation Climatology Centre (GPCC) are also compared with GLDAS forcing precipitation data. Large errors and lack of monthly variability in GLDAS-1996 precipitation data are the main sources for the anomalies in the simulated runoff. The impact of the precipitation data on simulated runoff for 1996 is investigated with the Community Atmosphere Biosphere Land Exchange (CABLE) land-surface model in the Yangtze basin, for which area high-quality local precipitation data are obtained from the China Meteorological Administration (CMA). The CABLE model is driven by GLDAS daily precipitation data and CMA daily precipitation, respectively. The simulated daily and monthly runoffs obtained from CMA data are noticeably better than those obtained from GLDAS data, suggesting that GLDAS-1996 precipitation data are not so reliable for land-surface flux simulations.

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Development and application of the WRFPLUS-Chem online chemistry adjoint and WRFDA-Chem assimilation system

Geoscientific Model Development ◽

10.5194/gmd-8-1857-2015 ◽

2015 ◽

Vol 8 (6) ◽

pp. 1857-1876 ◽

Cited By ~ 11

Author(s):

J. J. Guerrette ◽

D. K. Henze

Keyword(s):

Land Surface ◽

Vertical Mixing ◽

Model Performance ◽

Land Surface Model ◽

Sensitivity Study ◽

Climate Impacts ◽

Surface Model ◽

Time Period ◽

Develop Land ◽

The Impact

Abstract. Here we present the online meteorology and chemistry adjoint and tangent linear model, WRFPLUS-Chem (Weather Research and Forecasting plus chemistry), which incorporates modules to treat boundary layer mixing, emission, aging, dry deposition, and advection of black carbon aerosol. We also develop land surface and surface layer adjoints to account for coupling between radiation and vertical mixing. Model performance is verified against finite difference derivative approximations. A second-order checkpointing scheme is created to reduce computational costs and enable simulations longer than 6 h. The adjoint is coupled to WRFDA-Chem, in order to conduct a sensitivity study of anthropogenic and biomass burning sources throughout California during the 2008 Arctic Research of the Composition of the Troposphere from Aircraft and Satellites (ARCTAS) field campaign. A cost-function weighting scheme was devised to reduce the impact of statistically insignificant residual errors in future inverse modeling studies. Results of the sensitivity study show that, for this domain and time period, anthropogenic emissions are overpredicted, while wildfire emission error signs vary spatially. We consider the diurnal variation in emission sensitivities to determine at what time sources should be scaled up or down. Also, adjoint sensitivities for two choices of land surface model (LSM) indicate that emission inversion results would be sensitive to forward model configuration. The tools described here are the first step in conducting four-dimensional variational data assimilation in a coupled meteorology–chemistry model, which will potentially provide new constraints on aerosol precursor emissions and their distributions. Such analyses will be invaluable to assessments of particulate matter health and climate impacts.

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