2013
DOI: 10.5194/tc-7-129-2013
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Ice tectonic deformation during the rapid in situ drainage of a supraglacial lake on the Greenland Ice Sheet

Abstract: Abstract. We present detailed records of lake discharge, ice motion and passive seismicity capturing the behaviour and processes preceding, during and following the rapid drainage of a ∼ 4 km 2 supraglacial lake through 1.1-km-thick ice on the western margin of the Greenland Ice Sheet. Peak discharge of 3300 m 3 s −1 coincident with maximal rates of vertical uplift indicates that surface water accessed the ice-bed interface causing widespread hydraulic separation and enhanced basal motion. The differential mot… Show more

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Cited by 111 publications
(247 citation statements)
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References 38 publications
(52 reference statements)
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“…Channel formation could however be preconditioned by basal topography, the presence or otherwise of debris-laden basal ice [78] and permeable remnants of previous drainage systems [70, 83•]. In addition, following both initial lake and moulin drainage to the bed, there is often a substantial uplift of~0.1-1 m driven by ice bed separation [9,41,55] suggesting that it may be more realistic for models, driven by surface inputs, to initiate channels with considerably larger dimensions.…”
Section: Discussion Regarding Future Prioritiesmentioning
confidence: 99%
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“…Channel formation could however be preconditioned by basal topography, the presence or otherwise of debris-laden basal ice [78] and permeable remnants of previous drainage systems [70, 83•]. In addition, following both initial lake and moulin drainage to the bed, there is often a substantial uplift of~0.1-1 m driven by ice bed separation [9,41,55] suggesting that it may be more realistic for models, driven by surface inputs, to initiate channels with considerably larger dimensions.…”
Section: Discussion Regarding Future Prioritiesmentioning
confidence: 99%
“…The lakes can either drain rapidly by hydrofracture [9,41,42] or more slowly by overtopping their topographic lip and draining supraglacially downstream [43][44][45]; a 5-year study of 2000 Greenland-wide supraglacial lakes estimated that 13% of the lakes were 'fast-draining' (< 2 days) [35], while a 10-year catchment-based study of~200 lakes estimated that 28% of the lakes drained 'rapidly' (< 4 days) [38]. Rapid lake drainage results in large volumes of water entering the subglacial drainage system in a few hours with rates of 8700 and 3300 m 3 s −1 recorded [9,41]. In order for surface lakes to drain, an appropriate stress regime in the ice is required with existing crevasses, which can then be exploited and expanded by ponded surface waters draining englacially via hydrofracture [46][47][48].…”
Section: Supraglacial Meltwater Processesmentioning
confidence: 99%
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“…These landterminating outlet glaciers have been a focus of field-based research investigating subglacial hydrology (e.g., Chandler et al, 2013;Meierbachtol et al, 2013), lake drainage dynamics (Doyle et al, 2013;Dow et al, 2015), and meltwater influences on ice motion (e.g., Palmer et al, 2011;Bartholomew et al, 2012). The inland extent of the study domain reaches elevations of ∼2300 m, and is selected based on the fidelity of InSAR velocity measurements, which degrade toward the ice sheet interior where control points are either based on balance velocity or are 100 s of km away from bedrock reference points (Joughin et al, 2010).…”
Section: Study Area and Datasetsmentioning
confidence: 99%