Direct observations of evolving subglacial drainage beneath the Greenland Ice Sheet

Abstract. We use the Shreve hydraulic potential equation as a simplified approach to investigate potential subglacial lake locations and meltwater drainage pathways beneath the Antarctic and Greenland ice sheets. We validate the method by demonstrating its ability to recall the locations of >60% of the known subglacial lakes beneath the Antarctic Ice Sheet. This is despite uncertainty in the ice-sheet bed elevation and our simplified modelling approach. However, we predict many more lakes than are observed. Hence we suggest that thousands of subglacial lakes remain to be found. Applying our technique to the Greenland Ice Sheet, where very few subglacial lakes have so far been observed, recalls 1607 potential lake locations, covering 1.2% of the bed. Our results will therefore provide suitable targets for geophysical surveys aimed at identifying lakes beneath Greenland. We also apply the technique to modelled past ice-sheet configurations and find that during deglaciation both ice sheets likely had more subglacial lakes at their beds. These lakes, inherited from past ice-sheet configurations, would not form under current surface conditions, but are able to persist, suggesting a retreating ice-sheet will have many more subglacial lakes than advancing ones. We also investigate subglacial drainage pathways of the present-day and former Greenland and Antarctic ice sheets. Key sectors of the ice sheets, such as the Siple Coast (Antarctica) and NE Greenland Ice Stream system, are suggested to have been susceptible to subglacial drainage switching. We discuss how our results impact our understanding of meltwater drainage, basal lubrication and ice-stream formation.

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Evolution of the subglacial drainage system beneath the Greenland Ice Sheet revealed by tracers

Nature Geoscience ◽

10.1038/ngeo1737 ◽

2013 ◽

Vol 6 (3) ◽

pp. 195-198 ◽

Cited By ~ 145

Author(s):

D. M. Chandler ◽

J. L. Wadham ◽

G. P. Lis ◽

T. Cowton ◽

A. Sole ◽

...

Keyword(s):

Ice Sheet ◽

Drainage System ◽

Greenland Ice Sheet ◽

Subglacial Drainage

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High-resolution modelling of the seasonal evolution of surface water storage on the Greenland Ice Sheet

The Cryosphere Discussions ◽

10.5194/tcd-7-6143-2013 ◽

2013 ◽

Vol 7 (6) ◽

pp. 6143-6170 ◽

Cited By ~ 1

Author(s):

N. S. Arnold ◽

A. F. Banwell ◽

I. C. Willis

Keyword(s):

Surface Water ◽

High Resolution ◽

Water Storage ◽

Ice Sheet ◽

Drainage System ◽

Greenland Ice Sheet ◽

Water Volume ◽

Seasonal Evolution ◽

Surface Water Storage ◽

Subglacial Drainage

Abstract. Seasonal meltwater lakes on the Greenland Ice Sheet form when surface runoff is temporarily trapped in surface topographic depressions. The development of such lakes affects both the surface energy balance and dynamics of the ice sheet. Although areal extents, depths, and lifespans of lakes can be inferred from satellite imagery, such observational studies have a limited temporal resolution. Here, we adopt a modelling-based strategy to estimate the seasonal evolution of surface water storage for the ~ 3600 km2 Paakitsoq region of W. Greenland. We use a high-resolution time dependent surface mass balance model to calculate surface melt, a supraglacial water routing model to calculate lake filling and a prescribed water-volume based threshold to predict lake drainage events. The model shows good agreement between modelled lake locations and volumes and those observed in 9 Landsat 7 ETM+ images from 2001, 2002 and 2005. We use the model to investigate the lake water volume required to trigger drainage, and the impact that this threshold volume has on the proportion of meltwater that runs off the ice supraglacially, is stored in surface lakes, or enters the subglacial drainage system. Model performance is maximised with prescribed lake volume thresholds between 4000 and 7500 times the local ice thickness. For these thresholds, lakes transiently store < 40% of meltwater at the beginning of the melt season, decreasing to ~ 5 to 10% by the middle of the melt season. 40 to 50% of meltwater runs off the ice surface directly, and the remainder enters the subglacial drainage system through moulins at the bottom of drained lakes.

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The meltwater feedbacks on ice dynamics, influence of melt amplitude, duration and extent.

10.5194/egusphere-egu21-1099 ◽

2021 ◽

Author(s):

Basile de Fleurian ◽

Petra M. Langebroeke ◽

Richard Davy

Keyword(s):

Water Pressure ◽

Ice Sheet ◽

Drainage System ◽

Greenland Ice Sheet ◽

System Model ◽

Ice Dynamics ◽

Mountain Glaciers ◽

Different Characteristics ◽

Crucial Parameter ◽

Subglacial Drainage

In recent years, temperatures over the Greenland ice sheet have been rising, leading to an increase in surface melt. This increase however can not be reduced to a simple number. Throughout the recent years we have seen some extreme melt seasons with melt extending over the whole surface of the ice sheet (2012) or melt seasons of lower amplitudes but with a longer duration (2010). The effect of those variations on the subglacial system and hence on ice dynamic are poorly understood and are still mainly deduced from studies based on mountain glaciers.Here we apply the Ice-sheet and Sea-level System Model (ISSM) to a synthetic glacier with a geometry similar to a Greenland ice sheet land terminating glacier. The forcing is designed such that it allows to investigate different characteristics of the melt season: its length, intensity or the spatial extension of the melt. Subglacial hydrology and ice dynamics are coupled within ISSM is coupled to a subglacial hydrology model, allowing to study the response of the system in terms of subglacial water pressure and the final impact on ice dynamics. Of particular interest is the evolution of the distribution of the efficient and inefficient component of the subglacial drainage system which directly impacts the water pressure evolution at the base of the glacier.We note that the initiation of the melt season and the intensity of the melt at this period is a crucial parameter when studying the dynamic response of the glacier to different melt season characteristics. From those results, we can infer a more precise evolution of the dynamics of land terminating glaciers that are heavily driven by their subglacial drainage system. We also highlight which changes in the melt season pattern would be the most damageable for glacier stability in the future.

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Seasonal Variations in the Flow of Land-Terminating Glaciers in Central-West Greenland Using Sentinel-1 Imagery

Remote Sensing ◽

10.3390/rs10121878 ◽

2018 ◽

Vol 10 (12) ◽

pp. 1878 ◽

Cited By ~ 2

Author(s):

Adriano Lemos ◽

Andrew Shepherd ◽

Malcolm McMillan ◽

Anna Hogg

Keyword(s):

Ice Sheet ◽

Drainage System ◽

Greenland Ice Sheet ◽

Sheet Flow ◽

Altitudinal Variation ◽

Weekly Basis ◽

Ice Flow ◽

Temporal Sampling ◽

First Time ◽

Subglacial Drainage

Land-terminating sectors of the Greenland ice sheet flow faster in summer after surface meltwater reaches the subglacial drainage system. Speedup occurs when the subglacial drainage system becomes saturated, leading to a reduction in the effective pressure which promotes sliding of the overlying ice. Here, we use observations acquired by the Sentinel-1a and b synthetic aperture radar to track changes in the speed of land-terminating glaciers across a 14,000 km2 sector of west-central Greenland on a weekly basis in 2016 and 2017. The fine spatial and temporal sampling of the satellite data allows us to map the speed of summer and winter across the entire sector and to resolve the weekly evolution of ice flow across the downstream portions of five glaciers. Near to the ice sheet margin (at 650 m.a.s.l.), glacier speedup begins around day 130, persisting for around 90 days, and then peaks around day 150. At four of the five glaciers included in our survey the peak speedup is similar in both years, in Russell Glacier there is marked interannual variability of 32% between 2016 and 2017. We present, for the first time, seasonal and altitudinal variation in speedup persistence. Our study demonstrates the value of Sentinel-1’s systematic and frequent acquisition plan for studying seasonal changes in ice sheet flow.

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Surface-atmosphere decoupling limits accumulation at Summit, Greenland

Science Advances ◽

10.1126/sciadv.1501704 ◽

2016 ◽

Vol 2 (4) ◽

pp. e1501704 ◽

Cited By ~ 12

Author(s):

Max Berkelhammer ◽

David C. Noone ◽

Hans Christian Steen-Larsen ◽

Adriana Bailey ◽

Christopher J. Cox ◽

...

Keyword(s):

Accumulation Rate ◽

Ice Sheet ◽

Greenland Ice Sheet ◽

Ice Cores ◽

Moisture Flux ◽

Blowing Snow ◽

Direct Observations ◽

Surface Condensation ◽

Significant Area ◽

Isotopic Signal

Despite rapid melting in the coastal regions of the Greenland Ice Sheet, a significant area (~40%) of the ice sheet rarely experiences surface melting. In these regions, the controls on annual accumulation are poorly constrained owing to surface conditions (for example, surface clouds, blowing snow, and surface inversions), which render moisture flux estimates from myriad approaches (that is, eddy covariance, remote sensing, and direct observations) highly uncertain. Accumulation is partially determined by the temperature dependence of saturation vapor pressure, which influences the maximum humidity of air parcels reaching the ice sheet interior. However, independent proxies for surface temperature and accumulation from ice cores show that the response of accumulation to temperature is variable and not generally consistent with a purely thermodynamic control. Using three years of stable water vapor isotope profiles from a high altitude site on the Greenland Ice Sheet, we show that as the boundary layer becomes increasingly stable, a decoupling between the ice sheet and atmosphere occurs. The limited interaction between the ice sheet surface and free tropospheric air reduces the capacity for surface condensation to achieve the rate set by the humidity of the air parcels reaching interior Greenland. The isolation of the surface also acts to recycle sublimated moisture by recondensing it onto fog particles, which returns the moisture back to the surface through gravitational settling. The observations highlight a unique mechanism by which ice sheet mass is conserved, which has implications for understanding both past and future changes in accumulation rate and the isotopic signal in ice cores from Greenland.

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Correspondence

Journal of Glaciology ◽

10.3189/2015jog14j197 ◽

2015 ◽

Vol 61 (225) ◽

pp. 202-204 ◽

Cited By ~ 1

Author(s):

Christian Helanow ◽

Toby Meierbachtol ◽

Peter Jansson

Keyword(s):

Data Collection ◽

Ice Sheet ◽

Drainage System ◽

Greenland Ice Sheet ◽

Close Correlation ◽

Satisfactory Description ◽

Physical Integrity ◽

Ice Velocity ◽

Process Level ◽

Subglacial Drainage

Recent efforts have been made to increase our understanding of the dynamics of ice-sheet hydrology. Notably, much work has focused on the southwest sector of the Greenland ice sheet (GrIS), with intense data collection on diurnal to interannual timescales (e.g. Bartholomew and others, 2012; Cowton and others, 2013; Doyle and others, 2013). Observations show a close correlation between surface meltwater production and the seasonal ice-sheet acceleration, and it is a well-accepted hypothesis that an increase in the former drives the latter via meltwater transfer through the subglacial drainage system (e.g. Zwally and others, 2002). However, due to the remote nature and complexity of the subglacial domain, a satisfactory description at the process level has remained elusive. Better understanding of the coupling of meltwater forcing on ice velocity through the subglacial component is therefore necessary to improve the physical integrity of ice-sheet models.

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The annual glaciohydrology cycle in the ablation zone of the Greenland ice sheet: Part 1. Hydrology model

Journal of Glaciology ◽

10.3189/002214311797409668 ◽

2011 ◽

Vol 57 (204) ◽

pp. 697-709 ◽

Cited By ~ 38

Author(s):

William Colgan ◽

Harihar Rajaram ◽

Robert Anderson ◽

Konrad Steffen ◽

Thomas Phillips ◽

...

Keyword(s):

Residence Time ◽

Ice Sheet ◽

Greenland Ice Sheet ◽

Hydraulic Head ◽

Ablation Zone ◽

Hydrology Model ◽

Hydrologic System ◽

Speed Up ◽

Ice Velocity ◽

Subglacial Drainage

AbstractWe apply a novel one-dimensional glacier hydrology model that calculates hydraulic head to the tidewater-terminating Sermeq Avannarleq flowline of the Greenland ice sheet. Within a plausible parameter space, the model achieves a quasi-steady-state annual cycle in which hydraulic head oscillates close to flotation throughout the ablation zone. Flotation is briefly achieved during the summer melt season along a ∼17 km stretch of the ∼50 km of flowline within the ablation zone. Beneath the majority of the flowline, subglacial conduit storage ‘closes’ (i.e. obtains minimum radius) during the winter and ‘opens’ (i.e. obtains maximum radius) during the summer. Along certain stretches of the flowline, the model predicts that subglacial conduit storage remains open throughout the year. A calculated mean glacier water residence time of ∼2.2 years implies that significant amounts of water are stored in the glacier throughout the year. We interpret this residence time as being indicative of the timescale over which the glacier hydrologic system is capable of adjusting to external surface meltwater forcings. Based on in situ ice velocity observations, we suggest that the summer speed-up event generally corresponds to conditions of increasing hydraulic head during inefficient subglacial drainage. Conversely, the slowdown during fall generally corresponds to conditions of decreasing hydraulic head during efficient subglacial drainage.

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Refreezing on the Greenland ice sheet: a comparison of parameterizations

The Cryosphere Discussions ◽

10.5194/tcd-5-2723-2011 ◽

2011 ◽

Vol 5 (5) ◽

pp. 2723-2764 ◽

Cited By ~ 1

Author(s):

C. H. Reijmer ◽

M. R. van den Broeke ◽

J. Ettema ◽

L. B. Stap

Keyword(s):

Climate Model ◽

Ice Sheet ◽

Greenland Ice Sheet ◽

Liquid Water Content ◽

Annual Variations ◽

Output Surface ◽

Direct Observations ◽

Mass Balance Models ◽

Snow Model ◽

Regional Atmospheric Climate Model

Abstract. Retention and refreezing of meltwater are acknowledged to be important processes for the mass budget of polar glaciers and ice sheets. Several parameterizations of these processes exist for use in energy and mass balance models. Due to a lack of direct observations, validation of these parameterizations is difficult. In this study we compare a set of 6 refreezing parameterizations against output of the Regional Atmospheric Climate Model (RACMO2), applied to the Greenland ice sheet. In RACMO2, refreezing is explicitly calculated in a snow model that calculates vertical profiles of temperature, density and liquid water content. For consistency, the parameterizations are forced with output (surface temperature, precipitation and melt) of RACMO2. For the ice sheet-integrated amount of refreezing and its inter-annual variations, all parameterizations give similar results, especially after some tuning. However, the spatial distributions differ significantly. Results are especially sensitive to the choice of the depth of the thermally active layer, which determines the cold content of the snow in most parameterizations.

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