Towards long-term records of rain-on-snow events across the Arctic from satellite data
Permanent link
https://hdl.handle.net/10037/29840Date
2023-02-21Type
Journal articleTidsskriftartikkel
Peer reviewed
Author
Bartsch, Annett; Bergstedt, Helena; Pointner, Georg; Muri, Xaver; Rautiainen, Kimmo; Leppänen, Leena; Joly, Kyle; Sokolov, Aleksandr; Orekhov, Pavel; Ehrich, Dorothee; Soininen, Eeva MAbstract
Rain-on-snow (ROS) events occur across many regions of the terrestrial Arctic in mid-winter. Snowpack properties are changing, and in extreme cases ice layers form
which affect wildlife, vegetation and soils beyond the duration of the event. Specifically, satellite microwave observations have been shown to provide insight into known events.
Only Ku-band radar (scatterometer) has been applied so far
across the entire Arctic. Data availability at this frequency is
limited, however. The utility of other frequencies from passive and active systems needs to be explored to develop a
concept for long-term monitoring. The latter are of specific
interest as they can be potentially provided at higher spatial
resolution. Radar records have been shown to capture the associated snow structure change based on time-series analyses. This approach is also applicable when data gaps exist
and has capabilities to evaluate the impact severity of events.
Active as well as passive microwave sensors can also detect
wet snow at the timing of an ROS event if an acquisition
is available. The wet snow retrieval methodology is, however, rather mature compared to the identification of snow
structure change since ambiguous scattering behaviour needs
consideration. C-band radar is of special interest due to good
data availability including a range of nominal spatial resolutions (10 m–12.5 km). Scatterometer and SAR (synthetic
aperture radar) data have therefore been investigated. The
temperature dependence of C-band backscatter at VV (V –
vertical) polarization observable down to −40 ◦C is identified as a major issue for ROS retrieval but can be addressed
by a combination with a passive microwave wet snow indicator (demonstrated for Metop ASCAT – Advanced Scatterometer – and SMOS – Soil Moisture and Ocean Salinity). Results were compared to in situ observations (snowpit records,
caribou migration data) and Ku-band products. Ice crusts
were found in the snowpack after detected events (overall accuracy 82 %). The more crusts (events) there are, the
higher the winter season backscatter increase at C-band will
be. ROS events captured on the Yamal and Seward peninsulas have had severe impacts on reindeer and caribou, respectively, due to ice crust formation. SAR specifically from
Sentinel-1 is promising regarding ice layer identification at
better spatial details for all available polarizations. The fusion of multiple types of microwave satellite observations
is suggested for the creation of a climate data record, but
the consideration of performance differences due to spatial
and temporal cover, as well as microwave frequency, is crucial. Retrieval is most robust in the tundra biome, where results are comparable between sensors. Records can be used
to identify extremes and to apply the results for impact studies at regional scale.
Publisher
Copernicus PublicationsCitation
Bartsch, Bergstedt, Pointner, Muri, Rautiainen, Leppänen, Joly, Sokolov, Orekhov, Ehrich, Soininen. Towards long-term records of rain-on-snow events across the Arctic from satellite data. The Cryosphere. 2023;17(2):889-915Metadata
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