2024
DOI: 10.3389/feart.2024.1381323
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Remote sensing of mountain snow from space: status and recommendations

Simon Gascoin,
Kari Luojus,
Thomas Nagler
et al.

Abstract: The spatial and temporal variation of the seasonal snowpack in mountain regions is recognized as a clear knowledge gap for climate, ecology and water resources applications. Here, we identify three salient topics where recent developments in snow remote sensing and data assimilation can lead to significant progress: snow water equivalent, high resolution snow-covered area and long term snow cover observations including snow albedo. These topics can be addressed in the near future with institutional support.

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Cited by 5 publications
(1 citation statement)
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“…In fact, the network only represents a small spatial footprint of the seasonal snow zone and due to the limited elevations the network covers (Bales et al, 2006) and it may become less representative of total snowpack in a less snowy future (Hammond et al, 2023). Remote sensing products can help improve spatial coverage of snowpack estimates but can be hindered by infrequent satellite return time, vegetation cover, complex topography, cloud masking, and require assumptions to produce metrics such as snow water equivalent (SWE) (Gascoin et al, 2024;Rittger et al, 2020). Reanalysis products, which can combine point measurements, remotely sensed data, and physical modeling, often struggle because of a paucity of high-elevation precipitation and snowpack measurements to assimilate into the product as well as inherent problems with their coarse spatial resolution to represent snow-terrain and snow-vegetation interactions (Clow et al, 2012).…”
Section: Introductionmentioning
confidence: 99%
“…In fact, the network only represents a small spatial footprint of the seasonal snow zone and due to the limited elevations the network covers (Bales et al, 2006) and it may become less representative of total snowpack in a less snowy future (Hammond et al, 2023). Remote sensing products can help improve spatial coverage of snowpack estimates but can be hindered by infrequent satellite return time, vegetation cover, complex topography, cloud masking, and require assumptions to produce metrics such as snow water equivalent (SWE) (Gascoin et al, 2024;Rittger et al, 2020). Reanalysis products, which can combine point measurements, remotely sensed data, and physical modeling, often struggle because of a paucity of high-elevation precipitation and snowpack measurements to assimilate into the product as well as inherent problems with their coarse spatial resolution to represent snow-terrain and snow-vegetation interactions (Clow et al, 2012).…”
Section: Introductionmentioning
confidence: 99%