Abstract
Supraglacial liquid water at the margins of ice sheets has an important impact on the surface energy balance and can also influence the ice flow when supraglacial lakes drain to the bed. Optical imagery is able to monitor supraglacial lakes during the summer season. Here we developed an alternative method using polarimetric SAR from Sentinel-1 during 2017–2020 to distinguish between liquid water and other surface types at the margin of the Northeast Greenland Ice Stream. This allows the supraglacial hydrology to be monitored during the winter months too. We found that the majority of supraglacial lakes persist over winter. When comparing our results to optical data, we found significantly more water. Even during summer, many lakes are partly or fully covered by a lid of ice and snow. We used our classification results to automatically map the outlines of supraglacial lakes, create time series of water area for each lake, and hence detect drainage events. We even found several winter time drainages, which might have an important effect on ice flow. Our method has problems during the peak of the melt season, but for the rest of the year it provides crucial information for better understanding the component of supraglacial hydrology in the glaciological system.
Highlights
Each summer, numerous supraglacial lakes (SGLs) appear in the ablation zone of the Greenland Ice Sheet (GrIS)
A comparison with the quasi-simultaneous cloud-free optical S2 images revealed that large parts of many SGLs are still lake-ice covered, even in the peak of the melt season
In this paper we present an algorithm which is solely based on polarimetric SAR (PolSAR) data and is able to map and monitor SGLs automatically
Summary
Numerous supraglacial lakes (SGLs) appear in the ablation zone of the Greenland Ice Sheet (GrIS). These lakes form from accumulated meltwater in surface depressions [1] and can influence the mass balance of the ice sheet in several ways. The lake water has a lower albedo than the surrounding glacier, which increases the absorption of shortwave radiation and causes additional melting [2,3]. The large amounts of liquid water stored in SGLs can suddenly drain via crevasses or hydrofracturing, reach the base of the ice sheet and locally increase ice velocities due to reduced basal traction [4,5,6]. As observed by optical imagery, several lakes freeze over at the end of the ablation season [7] and get covered by the first snowfall
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