Role of discrete recharge from the supraglacial drainage system for
modelling of subglacial conduits pattern of Svalbard polythermal
glaciers

Decaux, Léo; Grabiec, Mariusz; Ignatiuk, Dariusz; Jania, Jacek

doi:10.5194/tc-2017-219

Cited by 3 publications

(5 citation statements)

References 22 publications

(35 reference statements)

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“…Small supraglacial streams are ubiquitous on the southwest GrIS yet are largely undetected in 30 m resolution Landsat 8 images (Yang and Smith, 2016; Yang and others, 2019b). Although small streams enhance surface meltwater routing (Decaux and others, 2018; Yang and others, 2018), coarser images of large supraglacial rivers capture the overall drainage pattern of supraglacial hydrologic networks effectively (see Table S1 and Fig. S2).…”

Section: Methodsmentioning

confidence: 99%

Seasonal evolution of supraglacial lakes and rivers on the southwest Greenland Ice Sheet

et al. 2021

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Supraglacial lakes and rivers dominate the storage and transport of meltwater on the southwest Greenland Ice Sheet (GrIS) surface. Despite functioning as interconnected hydrologic networks, supraglacial lakes and rivers are commonly studied as independent features, resulting in an incomplete understanding of their collective impact on meltwater storage and routing. We use Landsat 8 satellite imagery to assess the seasonal evolution of supraglacial lakes and rivers on the southwest GrIS during the 2015 melt season. Remotely sensed meltwater areas and volumes are compared with surface runoff simulations from three climate models (MERRA-2, MAR 3.6 and RACMO 2.3), and with in situ observations of proglacial discharge in the Watson River. We find: (1) at elevations >1600 m, 21% of supraglacial lakes and 28% of supraglacial rivers drain into moulins, signifying the presence of high-elevation surface-to-bed meltwater connections even during a colder-than-average melt season; (2) while supraglacial lakes dominate instantaneous surface meltwater storage, supraglacial rivers dominate total surface meltwater area and discharge; (3) the combined surface area of supraglacial lakes and rivers is strongly correlated with modeled surface runoff; and (4) of the three models examined here, MERRA-2 runoff yields the highest overall correlation with observed proglacial discharge in the Watson River.

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Section: Methodsmentioning

confidence: 99%

Seasonal evolution of supraglacial lakes and rivers on the southwest Greenland Ice Sheet

et al. 2021

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“…However, the spatial resolution of the Sentinel-2 images is three times higher than that of the Landsat-8 images and thus supraglacial drainage patterns are much better resolved in the Sentinel-derived map products (see close-up images, Figures 7 -9). Sentinel-mapped supraglacial river networks are also more continuous, which is crucial for investigating surface meltwater routing (King et al, 2016;Yang and Smith, 2016a;Smith et al, 2017;Decaux et al, 2018;Yang et al, 2018). On all three ice masses, supraglacial rivers generally flow from high-elevation slushy zones to low-elevation bare ice ablation zones.…”

Section: Comparison Of Sentinel-2 and Landsat-8 Mapped Supraglacial Rmentioning

confidence: 99%

“…The supraglacial drainage patterns mapped in this study have important implications for surface meltwater routing. Supraglacial river networks and their corresponding ice surface catchments determine the timing and magnitude of peak supraglacial river discharge and corresponding inputs to englacial and subglacial drainage systems through moulins (Smith et al, 2017;Decaux et al, 2018;Yang et al, 2018).…”

Section: Implications For Surface Meltwater Routingmentioning

confidence: 99%

“…Extensive, complex supraglacial river networks have been observed in the ablation zone of the southwest Greenland Ice Sheet (GrIS) (Thomsen et al, 1989;McGrath et al, 2011;Yang and Smith, 2013;Lampkin and VanderBerg, 2014;Poinar et al, 2015;Smith et al, 2015;Yang and Smith, 2016a;Koziol et al, 2017;Smith et al, 2017), the Antarctic Ice Sheet (Bell et al, 2017;Kingslake et al, 2017), some large ice caps/fields (e.g., Devon Ice Cap (Dowdeswell et al, 2004;Boon et al, 2010), and Juneau Ice Field (Marston, 1983;Karlstrom et al, 2014)) as well as smaller stream systems on many mountain glaciers (Stenborg, 1968;Hambrey, 1977;Knighton, 1985;Brykała, 1998;Rippin et al, 2015;Decaux et al, 2018). These surface drainage features impact the efficacy and speed of meltwater routing to the englacial, subglacial, and proglacial portions of glaciers and ice sheets (Stenborg, 1968;Marston, 1983;Smith et al, 2017;Decaux et al, 2018) and thus coupling processes of surface melt with subglacial hydrology and ice flow (Zwally et al, 2002;Bartholomew et al, 2011;Andrews et al, 2014;Poinar et al, 2015;Smith et al, 2015;Wyatt and Sharp, 2015;Karlstrom and Yang, 2016;Yang and Smith, 2016a;Smith et al, 2017). Where meltwater accumulates on ice shelves, hydrofracture of surface crevasses can trigger their rapid collapse, causing debuttressing and acceleration of upstream glaciers (Scambos et al, 2000;…”

Section: Introductionmentioning

confidence: 99%

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Supraglacial rivers on the northwest Greenland Ice Sheet, Devon Ice Cap, and Barnes Ice Cap mapped using Sentinel-2 imagery

Yang

Smith

Sole

et al. 2019

International Journal of Applied Earth Observation and Geoinfor

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Supraglacial rivers set efficacy and time lags by which surface meltwater is routed to the englacial, subglacial, and proglacial portions of ice masses. However, these hydrologic features remain poorly studied mainly because they are too narrow (typically <30 m) to be reliably delineated in conventional moderate-resolution satellite images (e.g., 30 m Landsat-8 imagery). This study demonstrates the utility of 10 m Sentinel-2 Multi-Spectral Instrument images to map supraglacial rivers on the northwest Greenland Ice Sheet, Devon Ice Cap, and Barnes Ice Cap, covering a total area of ~ 10,000 km 2. Sentinel-2 and Landsat-8 both capture overall supraglacial drainage patterns, but Sentinel-2 images are superior to Landsat-8 images for delineating narrow and continuous supraglacial rivers. Sentinel-2 mapping across the three study areas reveals a variety of supraglacial drainage patterns. In northwest Greenland near Inglefield Land, subparallel supraglacial rivers up to 55 km long drain meltwater directly off the ice sheet onto the proglacial zone. On the Devon and the Barnes ice caps, shorter supraglacial rivers (up to 15-30 km long) are commonly interrupted by moulins, which drain internally drained catchments on the ice surface to subglacial systems. We conclude that Sentinel-2 offers strong potential for investigating supraglacial meltwater drainage patterns and improving our understanding of the hydrological conditions of ice masses globally.

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“…For spatial analysis of air temperature and precipitation distributions, we used a digital elevation model (DEM) with a resolution of 100 m horizontally and ±5 m vertically, both estimated from Very High Resolution Satellite VHRS images from WorldView-2 (2015) [42].…”

Section: Methodsmentioning

confidence: 99%

The Role of Winter Rain in the Glacial System on Svalbard

Łupikasza

Ignatiuk

Grabiec

et al. 2019

Water

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Rapid Arctic warming results in increased winter rain frequencies, which may impact glacial systems. In this paper, we discuss climatology and precipitation form trends, followed by examining the influence of winter rainfall (Oct‒May) on both the mass balance and dynamics of Hansbreen (Svalbard). We used data from the Hornsund meteorological station (01003 WMO), in addition to the original meteorological and glaciological data from three measurement points on Hansbreen. Precipitation phases were identified based on records of weather phenomena and used—along with information on lapse rate—to estimate the occurrence and altitudinal extent of winter rainfall over the glacier. We found an increase in the frequency of winter rain in Hornsund, and that these events impact both glacier mass balance and glacier dynamics. However, the latter varied depending on the degree of snow cover and drainage systems development. In early winter, given the initial, thin snow cover and an inefficient drainage system, rainfall increased glacier velocity. Full-season winter rainfall on well-developed snow was effectively stored in the glacier, contributing on average to 9% of the winter accumulation.

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Role of discrete recharge from the supraglacial drainage system for modelling of subglacial conduits pattern of Svalbard polythermal glaciers

Cited by 3 publications

References 22 publications

Seasonal evolution of supraglacial lakes and rivers on the southwest Greenland Ice Sheet

Seasonal evolution of supraglacial lakes and rivers on the southwest Greenland Ice Sheet

Supraglacial rivers on the northwest Greenland Ice Sheet, Devon Ice Cap, and Barnes Ice Cap mapped using Sentinel-2 imagery

The Role of Winter Rain in the Glacial System on Svalbard

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