2018
DOI: 10.1029/2017jf004585
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Seasonal Evolution of the Subglacial Hydrologic System Modified by Supraglacial Lake Drainage in Western Greenland

Abstract: The impact of summer surface melt on Greenland Ice Sheet dynamics is modulated by the state of the subglacial hydrologic system. Studies of ice motion indicate that efficiency of the subglacial system increases over the melt season, decreasing the sensitivity of ice motion to surface melt inputs. However, the behavior of the subglacial hydrologic system is complex and some characteristics are still poorly constrained. Here we investigate the coevolution of subglacial hydrology and ice motion in the Pâkitsoq re… Show more

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Cited by 38 publications
(99 citation statements)
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References 97 publications
(246 reference statements)
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“…However, observations of the subglacial environment and constraints on crucial model parameters are sparse, leading to uncertainty in inferences from models: modelled R-channels can form under conditions representative of the upper ablation area if a large (∼1 m 2 ) initial conduit size is used (e.g., Hewitt, 2011;Gulley et al, 2012). Such conditions may occur due to uplift during rapid lake drainage (Das et al, 2008;Pimentel and Flowers, 2010;Andrews et al, 2018) or may be facilitated if persistent surface-to-bed hydrological connections (Catania and Neumann, 2010) enable erosion of preferential flow pathways into the substrate (Gulley et al, 2012;Beaud et al, 2018). In addition, the spatial pattern of surfaceto-bed connections (moulins) strongly influences the spatial organisation of modelled subglacial channels, with a high density of moulins producing widespread and rapid channelisation beneath ice up to 815 m thick (Banwell et al, 2016).…”
Section: Efficient Channel Formationmentioning
confidence: 99%
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“…However, observations of the subglacial environment and constraints on crucial model parameters are sparse, leading to uncertainty in inferences from models: modelled R-channels can form under conditions representative of the upper ablation area if a large (∼1 m 2 ) initial conduit size is used (e.g., Hewitt, 2011;Gulley et al, 2012). Such conditions may occur due to uplift during rapid lake drainage (Das et al, 2008;Pimentel and Flowers, 2010;Andrews et al, 2018) or may be facilitated if persistent surface-to-bed hydrological connections (Catania and Neumann, 2010) enable erosion of preferential flow pathways into the substrate (Gulley et al, 2012;Beaud et al, 2018). In addition, the spatial pattern of surfaceto-bed connections (moulins) strongly influences the spatial organisation of modelled subglacial channels, with a high density of moulins producing widespread and rapid channelisation beneath ice up to 815 m thick (Banwell et al, 2016).…”
Section: Efficient Channel Formationmentioning
confidence: 99%
“…Large inputs of meltwater to the bed during rapid lake drainage events also appear to influence the subglacial drainage system. Observations indicate ice sheet uplift during and immediately following rapid lake drainage (e.g., Das et al, 2008;Doyle et al, 2013;Andrews et al, 2018), followed by lowering within a few hours (e.g., Das et al, 2008;Bartholomew et al, 2012) to days (Doyle et al, 2013;Andrews et al, 2018), and sustained flow deceleration (Andrews et al, 2018). The uplift of the ice sheet-surface implies that the initial influx of runoff exceeds the capacity of the local subglacial drainage system (e.g., Das et al, 2008;Stevens et al, 2015) and likely spreads out radially from the point of input as a "blister" (Tsai and Rice, 2010;Dow et al, 2015).…”
Section: Efficient Channel Formationmentioning
confidence: 99%
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“…We next calculate principal strain rates from the 2011-2012 GPS network data from Andrews et al (2014Andrews et al ( , 2018. These data were recorded at 15-second intervals at eleven GPS stations separated by 2 to 20 km within a local network.…”
Section: Evolution Of Strain Rates At Gps Station-pair Midpointsmentioning
confidence: 99%