Back to Search Start Over

Fun at Antarctic grounding lines: Ice-shelf channels and sediment transport

Authors :
Drews, Reinhard
Mayer, Christoph
Eisen, Olaf
Helm, Veit
Ehlers, Todd
Pattyn, Frank
Berger, Sophie
Favier, Lionel
Hewitt, Ian H.
Ng, Felix
Fürst, Johannes
Gillet-Chaulet, Fabien
Bergeot, Nicolas
Matsuoka, Kenichi
Source :
EPIC3EGU General Assembly, Vienna, 2017-04-23-2017-04-28
Publication Year :
2017

Abstract

Meltwater beneath the polar ice sheets drains, in part, through subglacial conduits. Landforms created by such drainages are abundant in areas formerly covered by ice sheets during the last glacial maximum. However, observations of subglacial conduit dynamics under a contemporary ice sheet are lacking. We present results from ice-penetrating radar to infer the existence of subglacial conduits upstream of the grounding line of Roi Baudouin Ice Shelf, Antarctica. The conduits are aligned with ice-shelf channels, and underlain by esker ridges formed from sediment deposition due to reduced water outflow speed near the grounding line. In turn, the eskers modify localice flow to initiate the bottom topography of the ice-shelf channels, and create small surface ridges extending onto the shelf. Relict features on the shelf are interpreted to indicate a history of these interactions and variability of past subglacial drainages. Because ice-shelf channels are loci where intense melting occurs to thin an ice shelf, these findings expose a novel link between subglacial drainage, sedimentation, and ice-shelf stability. To investigate the role of sediment transport beneath ice sheets further, we model the sheet-shelf system ofthe Ekstömisen catchment, Antarctica. A 3D finite element model (Elmer/ICE) is used to solve the transients full Stokes equation for isotropic, isothermal ice with a dynamic grounding line. We initialize the model with surface topography from the TanDEM-X satellites and by inverting simultaneously for ice viscosity and basaldrag using present-day surface velocities. Results produce a flow field which is consitent with sattelite and on-site observations. Solving the age-depth relationship allows comparison with radar isochrones from airborne data, and gives information about the atmospheric/dynamic history of this sector. The flow field will eventually be used to identify potential sediment sources and sinks which we compare with more than 400 km of seismic profiles collected over the floating ice shelves and the grounded ice sheet.

Details

Database :
OpenAIRE
Journal :
EPIC3EGU General Assembly, Vienna, 2017-04-23-2017-04-28
Accession number :
edsair.od.......999..f5746be00e99787d6761e11328f201c3