Evaluation of homogenization methods for seasonal snow depth data in the Austrian Alps, 1930–2010

AbstractSnow depth mirrors regional climate change and is a vital parameter for medium- and long-term numerical climate prediction, numerical simulation of land-surface hydrological process, and water resource assessment. However, the quality of the available snow depth products retrieved from remote sensing is inevitably affected by cloud and mountain shadow, and the spatiotemporal resolution of the snow depth data cannot meet the need of hydrological research and decision-making assistance. Therefore, a method to enhance the accuracy of snow depth data is urgently required. In the present study, three kinds of snow depth data which included the D-InSAR data retrieved from the remote sensing images of Sentinel-1 synthetic aperture radar, the automatically measured data using ultrasonic snow depth detectors, and the manually measured data were assimilated based on ensemble Kalman filter. The assimilated snow depth data were spatiotemporally consecutive and integrated. Under the constraint of the measured data, the accuracy of the assimilated snow depth data was higher and met the need of subsequent research. The development of ultrasonic snow depth detector and the application of D-InSAR technology in snow depth inversion had greatly alleviated the insufficiency of snow depth data in types and quantity. At the same time, the assimilation of multi-source snow depth data by ensemble Kalman filter also provides high-precision data to support remote sensing hydrological research, water resource assessment, and snow disaster prevention and control program.

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Distributed snow and rock temperature modelling in steep rock walls using Alpine3D

The Cryosphere ◽

10.5194/tc-11-585-2017 ◽

2017 ◽

Vol 11 (1) ◽

pp. 585-607 ◽

Cited By ~ 12

Author(s):

Anna Haberkorn ◽

Nander Wever ◽

Martin Hoelzle ◽

Marcia Phillips ◽

Robert Kenner ◽

...

Keyword(s):

Energy Balance ◽

Snow Cover ◽

Snow Depth ◽

Spatial Scales ◽

Swiss Alps ◽

Balance Model ◽

Near Surface ◽

Surface Rock ◽

Depth Data ◽

Rock Temperature

Abstract. In this study we modelled the influence of the spatially and temporally heterogeneous snow cover on the surface energy balance and thus on rock temperatures in two rugged, steep rock walls on the Gemsstock ridge in the central Swiss Alps. The heterogeneous snow depth distribution in the rock walls was introduced to the distributed, process-based energy balance model Alpine3D with a precipitation scaling method based on snow depth data measured by terrestrial laser scanning. The influence of the snow cover on rock temperatures was investigated by comparing a snow-covered model scenario (precipitation input provided by precipitation scaling) with a snow-free (zero precipitation input) one. Model uncertainties are discussed and evaluated at both the point and spatial scales against 22 near-surface rock temperature measurements and high-resolution snow depth data from winter terrestrial laser scans.In the rough rock walls, the heterogeneously distributed snow cover was moderately well reproduced by Alpine3D with mean absolute errors ranging between 0.31 and 0.81 m. However, snow cover duration was reproduced well and, consequently, near-surface rock temperatures were modelled convincingly. Uncertainties in rock temperature modelling were found to be around 1.6 °C. Errors in snow cover modelling and hence in rock temperature simulations are explained by inadequate snow settlement due to linear precipitation scaling, missing lateral heat fluxes in the rock, and by errors caused by interpolation of shortwave radiation, wind and air temperature into the rock walls.Mean annual near-surface rock temperature increases were both measured and modelled in the steep rock walls as a consequence of a thick, long-lasting snow cover. Rock temperatures were 1.3–2.5 °C higher in the shaded and sunny rock walls, while comparing snow-covered to snow-free simulations. This helps to assess the potential error made in ground temperature modelling when neglecting snow in steep bedrock.

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The impact of snow products on detecting trends in sea ice thickness during the CryoSat-2 era

10.5194/egusphere-egu2020-18304 ◽

2020 ◽

Author(s):

Heidi Sallila ◽

Samantha Buzzard ◽

Eero Rinne ◽

Michel Tsamados

Keyword(s):

Sea Ice ◽

Snow Depth ◽

Ice Age ◽

Ice Thickness ◽

Sea Ice Thickness ◽

Seasonal Snow ◽

Uncertainty Estimates ◽

The One ◽

The Impact ◽

First Time

Retrieval of sea ice depth from satellite altimetry relies on knowledge of snow depth in the conversion of freeboard measurements to sea ice thickness. This remains the largest source of uncertainty in calculating sea ice thickness. In order to go beyond the use of a seasonal snow climatology, namely the one by Warren created from measurements collected during the drifting stations in 1937 and 1954&#8211;1991, we have developed as part of an ESA Arctic+ project several novel snow on sea ice pan-Arctic products, with the ultimate goal to resolve for the first time inter-annual and seasonal snow variability.Our products are inter-compared and calibrated with each other to guarantee multi-decadal continuity, and also compared with other recently developed snow on sea ice modelling and satellite based products. Quality assessment and uncertainty estimates are provided at a gridded level and as a function of sea ice cover characteristics such as sea ice age, and sea ice type.We investigate the impact of the spatially and temporally varying snow products on current satellite estimates of sea ice thickness and provide an update on the sea ice thickness uncertainties. We pay particular attention to potential biases of the seasonal ice growth and inter-annual trends.

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Towards a scale-independent fractional snow-covered area parameterization for complex terrain

10.5194/egusphere-egu2020-14575 ◽

2020 ◽

Author(s):

Nora Helbig ◽

Yves Bühler ◽

Lucie Eberhard ◽

César Deschamps-Berger ◽

Simon Gascoin ◽

...

Keyword(s):

Snow Depth ◽

Hydrological Modeling ◽

Spatial Scales ◽

Ground Surface ◽

Longwave Radiation ◽

Data Sets ◽

Depth Data ◽

Snow Covered Area ◽

Covered Area ◽

Wide Range

Whenever there is snow on the ground, there will be large spatial variability in snow depth. The spatial distribution of snow is significantly influenced by topography due to wind, precipitation, shortwave and longwave radiation, and even snow avalanches relocate the accumulated snow. Fractional snow-covered area (fSCA) is an important model parameter characterizing the fraction of the ground surface that is covered by snow and is crucial for various model applications such as weather forecasts, climate simulations and hydrological modeling.We recently suggested an empirical fSCA parameterization based on two spatial snow depth data sets acquired at peak of winter in Switzerland and Spain, which yielded best performance for spatial scales larger than 1000 m. However, this parameterization was not validated on independent snow depth data. To evaluate and improve our fSCA parameterization, in particular with regards to other spatial scales and snow climates (or geographic regions), we used spatial snow depth data sets form a wide range of mountain ranges in USA, Switzerland and France acquired by 5 different measuring methods. Pooling all snow depth data sets suggests that a scale-dependent parameter should be introduced to improve the fSCA parameterization, in particular for sub-kilometer spatial scales. Extending our empirical fSCA parameterization to a broader range of scales and snow climates is an important step towards accounting for spatio-temporal variability in snow depth in multiple snow model applications.

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Snow depth derived from passive microwave remote-sensing data in China

Annals of Glaciology ◽

10.3189/172756408787814690 ◽

2008 ◽

Vol 49 ◽

pp. 145-154 ◽

Cited By ~ 164

Author(s):

Tao Che ◽

Xin Li ◽

Rui Jin ◽

Richard Armstrong ◽

Tingjun Zhang

Keyword(s):

Remote Sensing ◽

Snow Cover ◽

Snow Depth ◽

Temporal Distribution ◽

Remote Sensing Data ◽

Passive Microwave ◽

Spatial And Temporal Distribution ◽

Sensing Data ◽

Seasonal Snow ◽

Snow Mass

AbstractIn this study, we report on the spatial and temporal distribution of seasonal snow depth derived from passive microwave satellite remote-sensing data (e.g. SMMR from 1978 to 1987 and SMM/ I from 1987 to 2006) in China. We first modified the Chang algorithm and then validated it using meteorological observation data, considering the influences from vegetation, wet snow, precipitation, cold desert and frozen ground. Furthermore, the modified algorithm is dynamically adjusted based on the seasonal variation of grain size and snow density. Snow-depth distribution is indirectly validated by MODIS snow-cover products by comparing the snow-extent area from this work. The final snow-depth datasets from 1978 to 2006 show that the interannual snow-depth variation is very significant. The spatial and temporal distribution of snow depth is illustrated and discussed, including the steady snow-cover regions in China and snow-mass trend in these regions. Though the areal extent of seasonal snow cover in the Northern Hemisphere indicates a weak decrease over a long period, there is no clear trend in change of snow-cover area extent in China. However, snow mass over the Qinghai–Tibetan Plateau and northwestern China has increased, while it has weakly decreased in northeastern China. Overall, snow depth in China during the past three decades shows significant interannual variation, with a weak increasing trend.

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Climatology and variability of historical Soviet snow depth data: some new perspectives in snow - Indian monsoon teleconnections

Climate Dynamics ◽

10.1007/s003820050294 ◽

1999 ◽

Vol 15 (6) ◽

pp. 475-489 ◽

Cited By ~ 137

Author(s):

R. H. Kripalani ◽

A. Kulkarni

Keyword(s):

Snow Depth ◽

Indian Monsoon ◽

Depth Data

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Performance of the Standard Normal Homogeneity Test for the homogenization of mean seasonal snow depth time series

International Journal of Climatology ◽

10.1002/joc.4977 ◽

2017 ◽

Vol 37 ◽

pp. 1267-1277 ◽

Cited By ~ 7

Author(s):

Giorgia Marcolini ◽

Alberto Bellin ◽

Gabriele Chiogna

Keyword(s):

Time Series ◽

Snow Depth ◽

Homogeneity Test ◽

Seasonal Snow ◽

Standard Normal Homogeneity Test ◽

Standard Normal

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Elevation dependency of mountain snow depth

The Cryosphere Discussions ◽

10.5194/tcd-8-3665-2014 ◽

2014 ◽

Vol 8 (4) ◽

pp. 3665-3698 ◽

Cited By ~ 2

Author(s):

T. Grünewald ◽

Y. Bühler ◽

M. Lehning

Keyword(s):

Snow Depth ◽

Elevation Gradient ◽

Systematic Evaluation ◽

Data Sets ◽

Elevation Gradients ◽

Depth Data ◽

Typical Shape ◽

Depth Relationship ◽

Snow Fall ◽

Depth Curves

Abstract. Elevation strongly affects quantity and distribution of precipitation and snow. Positive elevation gradients were identified by many studies, usually based on data from sparse precipitation stations or snow depth measurements. We present a systematic evaluation of the elevation – snow depth relationship. We analyse areal snow depth data obtained by remote sensing for seven mountain sites. Snow depths were averaged to 100 m elevation bands and then related to their respective elevation level. The assessment was performed at three scales ranging from the complete data sets by km-scale sub-catchments to slope transects. We show that most elevation – snow depth curves at all scales are characterised through a single shape. Mean snow depths increase with elevation up to a certain level where they have a distinct peak followed by a decrease at the highest elevations. We explain this typical shape with a generally positive elevation gradient of snow fall that is modified by the interaction of snow cover and topography. These processes are preferential deposition of precipitation and redistribution of snow by wind, sloughing and avalanching. Furthermore we show that the elevation level of the peak of mean snow depth correlates with the dominant elevation level of rocks.

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Sentinel-1 snow depth retrieval at sub-kilometer resolution over the European Alps

10.5194/tc-2021-74 ◽

2021 ◽

Author(s):

Hans Lievens ◽

Isis Brangers ◽

Hans-Peter Marshall ◽

Tobias Jonas ◽

Marc Olefs ◽

...

Keyword(s):

Snow Depth ◽

Snow Water Equivalent ◽

Weather Prediction ◽

Slight Reduction ◽

European Alps ◽

Mountainous Regions ◽

Seasonal Snow ◽

Spatio Temporal ◽

Snow Conditions ◽

Snow Mass

Abstract. Seasonal snow in mountain regions is an essential water resource. However, the spatio-temporal variability in mountain snow depth or snow water equivalent (SWE) from regional to global scales is not well understood due to the lack of high-resolution satellite observations and robust retrieval algorithms. We demonstrate the ability of the Sentinel-1 mission to monitor weekly snow depth at sub-kilometer (100 m, 300 m and 1 km) resolutions over the European Alps, for 2017–2019. Sentinel-1 backscatter observations, especially for the cross-polarization channel, show a high correlation with regional model simulations of snow depth over Austria and Switzerland. The observed changes in radar backscatter with the accumulation or ablation of snow are used in a change detection algorithm to retrieve snow depth. The algorithm includes the detection of dry and wet snow conditions. For dry snow conditions, the 1 km Sentinel-1 retrievals have a spatio-temporal correlation (R) of 0.87 and mean absolute error (MAE) of 0.17 m compared to in situ measurements across 743 sites in the European Alps. A slight reduction in performance is observed for the retrievals at 300 m (R = 0.85 and MAE = 0.18 m) and 100 m (R = 0.79 and MAE = 0.21 m). The results demonstrate the ability of Sentinel-1 to provide regional snow estimates at an unprecedented resolution in mountainous regions, where satellite-based estimates of snow mass are currently lacking. The retrievals can improve our knowledge of seasonal snow mass in areas with complex topography and benefit a number of applications, such as water resources management, flood forecasting and numerical weather prediction.

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