2021
Glacier melt is an important fresh water source. Seasonal changes can have impacting consequences on downstream water resources management. Today’s glacier monitoring lacks an observation-based tool for regional, sub-seasonal observation of glacier mass balance and a quantification of associated meltwater release at high temporal resolution. The snowline on a glacier marks the transition between the ice and snow surface, and is, at the end of the summer, a proxy for the annual glacier mass balance. It was shown that glacier mass balance model simulations closely tied to sub-seasonal snowline observations on optical satellite sensors are robust for the observation date. Recent advances in remote sensing permit efficient and extensive snowline mapping. Different methods automatically discriminate snow over ice on high- to medium-resolution optical satellite images. Other studies rely on lower ground resolution optical imagery to retrieve snow cover fraction at pixel level and produce regional maps of snow cover extent. However, state-of-the-art methods using optical sensors still have important shortcomings, such as cloud-cover related issues. Images acquired by Synthetic Aperture Radar (SAR), which are almost insensitive to cloud coverage, have proofed suitable for transient snowline delineation. The combination of SAR and optical data in a complementary way carries a unique potential for a better monitoring of snow depletion on high temporal and spatial resolution. The aim of this work is to map snow cover over glaciers by combining Sentinel-1 SAR, Sentinel-2 multispectral and lower resolution MODIS images. Consecutively, we developed an approach that can automatically handle classification of multi-source and multi-resolution satellite image stacks. This provides a unique solution for continuous snowline mapping since the beginning of the century. With the provided close-to-daily transient snow cover fractions on glacier level, we provide the basis for a new strategy to directly integrate multi-source satellite image classification into glacier mass balance monitoring.
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Observed snow depth trends in the European Alps: 1971 to 2019
Michael Matiu,
Alice Crespi,
Giacomo Bertoldi,
Carlo Maria Carmagnola,
Christoph Marty,
Samuel Morin,
Wolfgang Schöner,
Daniele Cat Berro,
Gabriele Chiogna,
Ludovica De Gregorio,
Sven Kotlarski,
Bruno Majone,
Gernot Resch,
Silvia Terzago,
Mauro Valt,
Walter Beozzo,
Paola Cianfarra,
Isabelle Gouttevin,
Giorgia Marcolini,
Claudia Notarnicola,
Marcello Petitta,
Simon C. Scherrer,
Ulrich Strasser,
Michael Winkler,
Marc Zebisch,
Andrea Cicogna,
R. Cremonini,
Andrea Debernardi,
Mattia Faletto,
Mauro Gaddo,
Lorenzo Giovannini,
Luca Mercalli,
Jean-Michel Soubeyroux,
Andrea Sušnik,
Alberto Trenti,
Stefano Urbani,
Viktor Weilguni
The Cryosphere, Volume 15, Issue 3
Abstract. The European Alps stretch over a range of climate zones which affect the spatial distribution of snow. Previous analyses of station observations of snow were confined to regional analyses. Here, we present an Alpine-wide analysis of snow depth from six Alpine countries – Austria, France, Germany, Italy, Slovenia, and Switzerland – including altogether more than 2000 stations of which more than 800 were used for the trend assessment. Using a principal component analysis and k-means clustering, we identified five main modes of variability and five regions which match the climatic forcing zones: north and high Alpine, north-east, north-west, south-east, and south and high Alpine. Linear trends of monthly mean snow depth between 1971 and 2019 showed decreases in snow depth for most stations from November to May. The average trend among all stations for seasonal (November to May) mean snow depth was −8.4 % per decade, for seasonal maximum snow depth −5.6 % per decade, and for seasonal snow cover duration −5.6 % per decade. Stronger and more significant trends were observed for periods and elevations where the transition from snow to snow-free occurs, which is consistent with an enhanced albedo feedback. Additionally, regional trends differed substantially at the same elevation, which challenges the notion of generalizing results from one region to another or to the whole Alps. This study presents an analysis of station snow depth series with the most comprehensive spatial coverage in the European Alps to date.
2020
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Observed snow depth trends in the European Alps 1971 to 2019
Michael Matiu,
Alice Crespi,
Giacomo Bertoldi,
Carlo Maria Carmagnola,
Christoph Marty,
Samuel Morin,
Wolfgang Schöner,
Daniele Cat Berro,
Gabriele Chiogna,
Ludovica De Gregorio,
Sven Kotlarski,
Bruno Majone,
Gernot Resch,
Silvia Terzago,
Mauro Valt,
Walter Beozzo,
Paola Cianfarra,
Isabelle Gouttevin,
Giorgia Marcolini,
Claudia Notarnicola,
Marcello Petitta,
Simon C. Scherrer,
Ulrich Strasser,
Michael Winkler,
Marc Zebisch,
Andrea Cicogna,
R. Cremonini,
Andrea Debernardi,
Mattia Faletto,
Mauro Gaddo,
Lorenzo Giovannini,
Luca Mercalli,
Jean‐Michel Soubeyroux,
Andrea Sušnik,
Alberto Trenti,
Stefano Urbani,
Viktor Weilguni
Abstract. The European Alps stretch over a range of climate zones, which affect the spatial distribution of snow. Previous analyses of station observations of snow were confined to regional analyses. Here, we present an Alpine wide analysis of snow depth from six Alpine countries: Austria, France, Germany, Italy, Slovenia, and Switzerland; including altogether more than 2000 stations. Using a principal component analysis and k-means clustering, we identified five main modes of variability and five regions, which match the climatic forcing zones: north and high Alpine, northeast, northwest, southeast and southwest. Linear trends of mean monthly snow depth between 1971 to 2019 showed decreases in snow depth for 87 % of the stations. December to February trends were on average −1.1 cm decade−1 (min, max: −10.8, 4.4; elevation range 0–1000 m), −2.5 (−25.1, 4.4; 1000–2000 m) and −0.1 (−23.3, 9.9; 2000–3000 m), with stronger trends in March to May: −0.6 (−10.9, 1.0; 0–1000 m), −4.6 (−28.1, 4.1; 1000–2000 m) and −7.6 (−28.3, 10.5; 2000–3000 m). However, regional trends differed substantially, which challenges the notion of generalizing results from one Alpine region to another or to the whole Alps. This study presents an analysis of station snow depth series with the most comprehensive spatial coverage in the European Alps to date.
2019
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A Novel Data Fusion Technique for Snow Cover Retrieval
Ludovica De Gregorio,
Mattia Callegari,
Carlo Marín,
Marc Zebisch,
Lorenzo Bruzzone,
Begüm Demir,
Ulrich Strasser,
Thomas Marke,
Daniel Günther,
Rudi Nadalet,
Claudia Notarnicola
IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing, Volume 12, Issue 8
This paper presents a novel data fusion technique for improving the snow cover monitoring for a mesoscale Alpine region, in particular in those areas where two information sources disagree. The presented methodological innovation consists in the integration of remote-sensing data products and the numerical simulation results by means of a machine learning classifier (support vector machine), capable to extract information from their quality measures. This differs from the existing approaches where remote sensing is only used for model tuning or data assimilation. The technique has been tested to generate a time series of about 1300 snow maps for the period between October 2012 and July 2016. The results show an average agreement between the fused product and the reference ground data of 96%, compared to 90% of the moderate-resolution imaging spectroradiometer (MODIS) data product and 92% of the numerical model simulation. Moreover, one of the most important results is observed from the analysis of snow cover area (SCA) time series, where the fused product seems to overcome the well-known underestimation of snow in forest of the MODIS product, by accurately reproducing the SCA peaks of winter season.
This paper presents a new concept to derive the snow water equivalent (SWE) based on the joint use of snow model (AMUNDSEN) simulation, ground data, and auxiliary products derived from remote sensing. The main objective is to characterize the spatial-temporal distribution of the model-derived SWE deviation with respect to the real SWE values derived from ground measurements. This deviation is due to the intrinsic uncertainty of any theoretical model, related to the approximations in the analytical formulation. The method, based on the k-NN algorithm, computes the deviation for some labeled samples, i.e., samples for which ground measurements are available, in order to characterize and model the deviations associated to unlabeled samples (no ground measurements available), by assuming that the deviations of samples vary depending on the location within the feature space. Obtained results indicate an improved performance with respect to AMUNDSEN model, by decreasing the RMSE and the MAE with ground data, on average, from 154 to 75 mm and from 99 to 45 mm, respectively. Furthermore, the slope of regression line between estimated SWE and ground reference samples reaches 0.9 from 0.6 of AMUNDSEN simulations, by reducing the data spread and the number of outliers.