Evidence for a water system transition beneath Thwaites Glacier, West Antarctica

Thwaites Glacier is one of the largest, most rapidly changing glaciers on Earth, and its landward-sloping bed reaches the interior of the marine West Antarctic Ice Sheet, which impounds enough ice to yield meters of sea-level rise. Marine ice sheets with landward-sloping beds have a potentially unstable configuration in which acceleration can initiate or modulate grounding-line retreat and ice loss. Subglacial water has been observed and theorized to accelerate the flow of overlying ice dependent on whether it is hydrologically distributed or concentrated. However, the subglacial water systems of Thwaites Glacier and their control on ice flow have not been characterized by geophysical analysis. The only practical means of observing these water systems is airborne ice-penetrating radar, but existing radar analysis approaches cannot discriminate between their dynamically critical states. We use the angular distribution of energy in radar bed echoes to characterize both the extent and hydrologic state of subglacial water systems across Thwaites Glacier. We validate this approach with radar imaging, showing that substantial water volumes are ponding in a system of distributed canals upstream of a bedrock ridge that is breached and bordered by a system of concentrated channels. The transition between these systems occurs with increasing surface slope, melt-water flux, and basal shear stress. This indicates a feedback between the subglacial water system and overlying ice dynamics, which raises the possibility that subglacial water could trigger or facilitate a grounding-line retreat in Thwaites Glacier capable of spreading into the interior of the West Antarctic Ice Sheet.

[1]  Andrew G. Fountain,et al.  Water flow through temperate glaciers , 1998 .

[2]  Byron D. Tapley,et al.  Accelerated Antarctic ice loss from satellite gravity measurements , 2009 .

[3]  D. Vaughan,et al.  Extensive dynamic thinning on the margins of the Greenland and Antarctic ice sheets , 2009, Nature.

[4]  B. Scheuchl,et al.  Ice Flow of the Antarctic Ice Sheet , 2011, Science.

[5]  Eric Rignot,et al.  Recent Antarctic ice mass loss from radar interferometry and regional climate modelling , 2008 .

[6]  J. Bamber,et al.  Reassessment of the Potential Sea-Level Rise from a Collapse of the West Antarctic Ice Sheet , 2009, Science.

[7]  J. Weertman Stability of ice‐age ice sheets , 1961 .

[8]  Sridhar Anandakrishnan,et al.  Outburst flooding and the initiation of ice-stream surges in response to climatic cooling: A hypothesis , 2006 .

[9]  Sridhar Anandakrishnan,et al.  Effect of Sedimentation on Ice-Sheet Grounding-Line Stability , 2007, Science.

[10]  Kenichi Matsuoka,et al.  Pitfalls in radar diagnosis of ice‐sheet bed conditions: Lessons from englacial attenuation models , 2011 .

[11]  Leigh A. Stearns,et al.  Increased flow speed on a large East Antarctic outlet glacier caused by subglacial floods , 2008 .

[12]  John W. Holt,et al.  Basal conditions for Pine Island and Thwaites Glaciers, West Antarctica, determined using satellite and airborne data , 2009, Journal of Glaciology.

[13]  Chung-Chi Lin,et al.  Radio Echo Sounding of Pine Island Glacier, West Antarctica: Aperture Synthesis Processing and Analysis of Feasibility From Space , 2007, IEEE Transactions on Geoscience and Remote Sensing.

[14]  R. Alley,et al.  A subglacial water-flow model for West Antarctica , 2009, Journal of Glaciology.

[15]  John B. Anderson,et al.  Paleo ice flow and subglacial meltwater dynamics in Pine Island Bay, West Antarctica , 2012 .

[16]  A. Fowler,et al.  Channelized subglacial drainage over a deformable bed , 1994 .

[17]  Martin J. Siegert,et al.  The Identification and Physiographical Setting of Antarctic Subglacial Lakes: An Update Based on Recent Discoveries , 2013 .

[18]  Takeo Kanade,et al.  Surface Reflection: Physical and Geometrical Perspectives , 1989, IEEE Trans. Pattern Anal. Mach. Intell..

[19]  L. Nicolaescu,et al.  Radar cross section , 2001, 5th International Conference on Telecommunications in Modern Satellite, Cable and Broadcasting Service. TELSIKS 2001. Proceedings of Papers (Cat. No.01EX517).

[20]  C. Schoof Ice sheet grounding line dynamics: Steady states, stability, and hysteresis , 2007 .

[21]  Dale P. Winebrenner,et al.  Modeling Englacial Radar Attenuation at Siple Dome, West Antarctica, Using Ice Chemistry and Temperature Data , 2006 .

[22]  John W. Holt,et al.  Using radar-sounding data to identify the distribution and sources of subglacial water: application to Dome C, East Antarctica , 2009 .

[23]  G. Oswald,et al.  Recovery of subglacial water extent from Greenland radar survey data , 2008, Journal of Glaciology.

[24]  M. E. Peters,et al.  New boundary conditions for the West Antarctic Ice Sheet: Subglacial topography of the Thwaites and Smith glacier catchments , 2006 .

[25]  C. Schoof,et al.  Drainage through subglacial water sheets , 2009 .

[26]  R. Alley,et al.  Water-Pressure Coupling of Sliding and Bed Deformation: I. Water System , 1989, Journal of Glaciology.

[27]  G. Oswald,et al.  Lakes Beneath the Antarctic Ice Sheet , 1973, Nature.

[28]  Jonathan L. Bamber,et al.  A new 1 km Digital Elevation Model of the Antarctic Derived From Combined Satellite Radar and Laser Data , 2008 .

[29]  A. Gades,et al.  Bed properties of Siple Dome and adjacent ice streams, West Antarctica, inferred from radio-echo sounding measurements , 2000, Journal of Glaciology.

[30]  R. Alley,et al.  Water-pressure Coupling of Sliding and Bed Deformation: III. Application to Ice Stream B, Antarctica , 1989, Journal of Glaciology.

[31]  M. E. Peters,et al.  Along-Track Focusing of Airborne Radar Sounding Data From West Antarctica for Improving Basal Reflection Analysis and Layer Detection , 2007, IEEE Transactions on Geoscience and Remote Sensing.