Direct measurements of meltwater runoff on the Greenland ice sheet surface

Significance Meltwater runoff is an important hydrological process operating on the Greenland ice sheet surface that is rarely studied directly. By combining satellite and drone remote sensing with continuous field measurements of discharge in a large supraglacial river, we obtained 72 h of runoff observations suitable for comparison with climate model predictions. The field observations quantify how a large, fluvial supraglacial catchment attenuates the magnitude and timing of runoff delivered to its terminal moulin and hence the bed. The data are used to calibrate classical fluvial hydrology equations to improve meltwater runoff models and to demonstrate that broad-scale surface water drainage patterns that form on the ice surface powerfully alter the timing, magnitude, and locations of meltwater penetrating into the ice sheet. Meltwater runoff from the Greenland ice sheet surface influences surface mass balance (SMB), ice dynamics, and global sea level rise, but is estimated with climate models and thus difficult to validate. We present a way to measure ice surface runoff directly, from hourly in situ supraglacial river discharge measurements and simultaneous high-resolution satellite/drone remote sensing of upstream fluvial catchment area. A first 72-h trial for a 63.1-km2 moulin-terminating internally drained catchment (IDC) on Greenland’s midelevation (1,207–1,381 m above sea level) ablation zone is compared with melt and runoff simulations from HIRHAM5, MAR3.6, RACMO2.3, MERRA-2, and SEB climate/SMB models. Current models cannot reproduce peak discharges or timing of runoff entering moulins but are improved using synthetic unit hydrograph (SUH) theory. Retroactive SUH applications to two older field studies reproduce their findings, signifying that remotely sensed IDC area, shape, and supraglacial river length are useful for predicting delays in peak runoff delivery to moulins. Applying SUH to HIRHAM5, MAR3.6, and RACMO2.3 gridded melt products for 799 surrounding IDCs suggests their terminal moulins receive lower peak discharges, less diurnal variability, and asynchronous runoff timing relative to climate/SMB model output alone. Conversely, large IDCs produce high moulin discharges, even at high elevations where melt rates are low. During this particular field experiment, models overestimated runoff by +21 to +58%, linked to overestimated surface ablation and possible meltwater retention in bare, porous, low-density ice. Direct measurements of ice surface runoff will improve climate/SMB models, and incorporating remotely sensed IDCs will aid coupling of SMB with ice dynamics and subglacial systems.

[1]  Franklin F. Snyder,et al.  Synthetic unit‐graphs , 1938 .

[2]  Van Te Chow,et al.  Handbook of applied hydrology : a compendium of water-resources technology , 1964 .

[3]  F. Müller,et al.  Errors in short-term ablation measurements on melting ice surfaces , 1969 .

[4]  M. Sharp,et al.  Borehole water-level variations and the structure of the subglacial hydrological system of Haut Glacier d’Arolla, Valais, Switzerland , 1995, Journal of Glaciology.

[5]  Thomas Konzelmann,et al.  Errors in daily ablation measurements in northern Greenland, 1993-94, and their implications for glacier climate studies , 1998, Journal of Glaciology.

[6]  R. Kwok,et al.  Detection of snowmelt regions on the Greenland ice sheet using diurnal backscatter change , 2001, Journal of Glaciology.

[7]  B. Brock,et al.  Effect of snowpack removal on energy balance, melt and runoff in a small supraglacial catchment , 2002 .

[8]  Konrad Steffen,et al.  Surface Melt-Induced Acceleration of Greenland Ice-Sheet Flow , 2002, Science.

[9]  S. P. Anderson,et al.  Response of glacier basal motion to transient water storage , 2007 .

[10]  C. J. P. P. Smeets,et al.  Large and Rapid Melt-Induced Velocity Changes in the Ablation Zone of the Greenland Ice Sheet , 2008, Science.

[11]  C. Veen,et al.  Partitioning of melt energy and meltwater fluxes in the ablation zone of the west Greenland ice sheet , 2008 .

[12]  M. R. van den Broeke,et al.  Partitioning Recent Greenland Mass Loss , 2009, Science.

[13]  Alun Hubbard,et al.  Greenland ice sheet motion coupled with daily melting in late summer , 2009 .

[14]  C. Schoof Ice-sheet acceleration driven by melt supply variability , 2010, Nature.

[15]  Jemma L. Wadham,et al.  Supraglacial forcing of subglacial drainage in the ablation zone of the Greenland ice sheet , 2010 .

[16]  G. Catania,et al.  Persistent englacial drainage features in the Greenland Ice Sheet , 2010 .

[17]  A. Hubbard,et al.  POLYTHERMAL GLACIER HYDROLOGY: A REVIEW , 2011 .

[18]  Konrad Steffen,et al.  Assessing the summer water budget of a moulin basin in the Sermeq Avannarleq ablation region, Greenland ice sheet , 2011, Journal of Glaciology.

[19]  Matthew J. Hoffman,et al.  Links between acceleration, melting, and supraglacial lake drainage of the western Greenland Ice Sheet , 2011 .

[20]  M. R. van den Broeke,et al.  The seasonal cycle and interannual variability of surface energy balance and melt in the ablation zone of the west Greenland ice sheet , 2011 .

[21]  Ian Hewitt,et al.  Seasonal changes in ice sheet motion due to melt water lubrication , 2012 .

[22]  Eric Rignot,et al.  Timing and origin of recent regional ice-mass loss in Greenland , 2012 .

[23]  J. Box,et al.  Evidence of meltwater retention within the Greenland ice sheet , 2012 .

[24]  Xavier Fettweis,et al.  Surface mass balance model intercomparison for the Greenland ice sheet , 2012 .

[25]  Xavier Fettweis,et al.  Evidence and analysis of 2012 Greenland records from spaceborne observations, a regional climate model and reanalysis data , 2012 .

[26]  Matt A. King,et al.  Short‐term variability in Greenland Ice Sheet motion forced by time‐varying meltwater drainage: Implications for the relationship between subglacial drainage system behavior and ice velocity , 2012 .

[27]  M. Saar,et al.  Quantifying the effects of glacier conduit geometry and recharge on proglacial hydrograph form , 2012 .

[28]  Eric Rignot,et al.  A Reconciled Estimate of Ice-Sheet Mass Balance , 2012, Science.

[29]  Xavier Fettweis,et al.  Simulating the growth of supraglacial lakes at the western margin of the Greenland ice sheet , 2012 .

[30]  Eric Rignot,et al.  A Reconciled Estimate of Ice-Sheet Mass Balance , 2012, Science.

[31]  K. Steffen,et al.  July 2012 Greenland melt extent enhanced by low-level liquid clouds , 2013, Nature.

[32]  Myoung-Jong Noh,et al.  An improved mass budget for the Greenland ice sheet , 2013 .

[33]  A. Hubbard,et al.  Evolution of the subglacial drainage system beneath the Greenland Ice Sheet revealed by tracers , 2013 .

[34]  Neil S. Arnold,et al.  Modeling subglacial water routing at Paakitsoq, W Greenland , 2013 .

[35]  G. Flowers,et al.  Modeling channelized and distributed subglacial drainage in two dimensions , 2013 .

[36]  S. Mishra,et al.  A review of the synthetic unit hydrograph: from the empirical UH to advanced geomorphological methods , 2014 .

[37]  A. B. Mikkelsen,et al.  A decade (2002–2012) of supraglacial lake volume estimates across Russell Glacier, West Greenland , 2014 .

[38]  A. Hubbard,et al.  Self-regulation of ice flow varies across the ablation area in south-west Greenland , 2014 .

[39]  J. D. Gulley,et al.  Direct observations of evolving subglacial drainage beneath the Greenland Ice Sheet , 2014, Nature.

[40]  X. Fettweis,et al.  Increasing meltwater discharge from the Nuuk region of the Greenland ice sheet and implications for mass balance (1960–2012) , 2014, Journal of Glaciology.

[41]  G. Liston,et al.  Near-surface internal melting: a substantial mass loss on Antarctic Dry Valley glaciers , 2014, Journal of Glaciology.

[42]  Ian Joughin,et al.  Limits to future expansion of surface‐melt‐enhanced ice flow into the interior of western Greenland , 2015 .

[43]  J. Lenaerts,et al.  Representing Greenland ice sheet freshwater fluxes in climate models , 2015 .

[44]  Colin J. Gleason,et al.  Technical Note: Semi-automated effective width extraction from time-lapse RGB imagery of a remote, braided Greenlandic river , 2015 .

[45]  Steen Savstrup Kristensen,et al.  Basin-scale partitioning of Greenland ice sheet mass balance components (2007–2011) , 2015 .

[46]  Colin J. Gleason,et al.  A Caution on the Use of Surface Digital Elevation Models to Simulate Supraglacial Hydrology of the Greenland Ice Sheet , 2015, IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing.

[47]  A. B. Mikkelsen,et al.  Subglacial water drainage, storage, and piracy beneath the Greenland ice sheet , 2015 .

[48]  M. Sharp,et al.  Linking surface hydrology to flow regimes and patterns of velocity variability on Devon Ice Cap, Nunavut , 2015 .

[49]  I. Overeem,et al.  River inundation suggests ice-sheet runoff retention , 2015 .

[50]  Colin J. Gleason,et al.  Efficient meltwater drainage through supraglacial streams and rivers on the southwest Greenland ice sheet , 2015, Proceedings of the National Academy of Sciences.

[51]  Ernst J. O. Schrama,et al.  Improved GRACE regional mass balance estimates of the Greenland Ice Sheet cross-validated with the input-output method (discussion paper) , 2015 .

[52]  R. Bell,et al.  Rerouting of subglacial water flow between neighboring glaciers in West Greenland , 2016 .

[53]  C. Clark,et al.  Ice stream activity scaled to ice sheet volume during Laurentide Ice Sheet deglaciation , 2016, Nature.

[54]  J. Box,et al.  The implication of nonradiative energy fluxes dominating Greenland ice sheet exceptional ablation area surface melt in 2012 , 2016 .

[55]  A. Hodson,et al.  Supraglacial weathering crust dynamics inferred from cryoconite hole hydrology , 2016 .

[56]  Laurence C. Smith,et al.  Internally drained catchments dominate supraglacial hydrology of the southwest Greenland Ice Sheet , 2016 .

[57]  Joel T. Harper,et al.  Measured basal water pressure variability of the western Greenland Ice Sheet: Implications for hydraulic potential , 2016 .

[58]  Colin J. Gleason,et al.  Characterizing supraglacial meltwater channel hydraulics on the Greenland Ice Sheet from in situ observations , 2016 .

[59]  C. Gleason,et al.  CryoSheds: a GIS modeling framework for delineating land-ice watersheds for the Greenland Ice Sheet , 2016 .

[60]  E. Mosley‐Thompson,et al.  Greenland meltwater storage in firn limited by near-surface ice formation , 2016 .

[61]  J. Ryan,et al.  Near surface meltwater storage in low-density bare ice of theGreenland ice sheet ablation zone , 2017 .

[62]  A. B. Mikkelsen,et al.  Hypsometric amplification and routing moderation of Greenland ice sheet meltwater release , 2017 .

[63]  A. Hubbard,et al.  Seismic evidence for complex sedimentary control of Greenland Ice Sheet flow , 2017, Science Advances.

[64]  S. Lhermitte,et al.  Firn meltwater retention on the Greenland Ice Sheet: a model comparison , 2017 .