4.6 Article

Challenges in predicting Greenland supraglacial lake drainages at the regional scale

Journal

CRYOSPHERE
Volume 15, Issue 3, Pages 1455-1483

Publisher

COPERNICUS GESELLSCHAFT MBH
DOI: 10.5194/tc-15-1455-2021

Keywords

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Funding

  1. National Aeronautics and Space Administration, Earth Sciences Division [80NSSC19K0054, NNH15CO48B]

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This study used remote-sensing data to analyze the relationship between strain rates and lake drainages in western Greenland. The study found that moulins associated with fast-draining lakes have significantly higher extensional background strain rates. However, the current ice sheet velocity products cannot accurately resolve the transient strain rates that drive fast lake drainages.
A leading hypothesis for the mechanism of fast supraglacial lake drainages is that transient extensional stresses briefly allow crevassing in otherwise compressional ice flow regimes. Lake water can then hydrofracture a crevasse to the base of the ice sheet, and river inputs can maintain this connection as a moulin. If future ice sheet models are to accurately represent moulins, we must understand their formation processes, timescales, and locations. Here, we use remote-sensing velocity products to constrain the relationship between strain rates and lake drainages across similar to 1600 km(2) in Pakitsoq, western Greenland, between 2002-2019. We find significantly more extensional background strain rates at moulins associated with fast-draining lakes than at slow-draining or non-draining lake moulins. We test whether moulins in more extensional background settings drain their lakes earlier, but we find insignificant correlation. To investigate the frequency at which strain-rate transients are associated with fast lake drainage, we examined Landsat-derived strain rates over 16 and 32 d periods at moulins associated with 240 fast-lake-drainage events over 18 years. A low signal-to-noise ratio, the presence of water, and the multi-week repeat cycle obscured any resolution of the hypothesized transient strain rates. Our results support the hypothesis that transient strain rates drive fast lake drainages. However, the current generation of ice sheet velocity products, even when stacked across hundreds of fast lake drainages, cannot resolve these transients. Thus, observational progress in understanding lake drainage initiation will rely on field-based tools such as GPS networks and photogrammetry.

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