Abstract
Abstract. Seismic reflection soundings of ice thickness and seabed depth were acquired on the Larsen C Ice Shelf in order to test a sub-ice shelf bathymetry model derived from the inversion of IceBridge gravity data. A series of lines was collected, from the Churchill Peninsula in the north to the Joerg Peninsula in the south, and also towards the ice front. Sites were selected using the bathymetry model derived from the inversion of free-air gravity data to indicate key regions where sub-ice shelf oceanic circulation may be affected by ice draft and seabed depth. The seismic velocity profile in the upper 100 m of firn and ice was derived from shallow refraction surveys at a number of locations. Measured temperatures within the ice column and at the ice base were used to define the velocity profile through the remainder of the ice column. Seismic velocities in the water column were derived from previous in situ measurements. Uncertainties in ice and water cavity thickness are in general < 10 m. Compared with the seismic measurements, the root-mean-square error in the gravimetrically derived bathymetry at the seismic sites is 162 m. The seismic profiles prove the non-existence of several bathymetric features that are indicated in the gravity inversion model, significantly modifying the expected oceanic circulation beneath the ice shelf. Similar features have previously been shown to be highly significant in affecting basal melt rates predicted by ocean models. The discrepancies between the gravity inversion results and the seismic bathymetry are attributed to the assumption of uniform geology inherent in the gravity inversion process and also the sparsity of IceBridge flight lines. Results indicate that care must be taken when using bathymetry models derived by the inversion of free-air gravity anomalies. The bathymetry results presented here will be used to improve existing sub-ice shelf ocean circulation models.
Highlights
Ice-shelf disintegration is of global significance due to two important processes
The rms error of the gravity inversion at 87 seismic sites is 162 m in bathymetry and 143 m in sub-ice shelf cavity thickness
Seismic measurements have been acquired at 87 sites across Larsen C Ice Shelf to constrain ice thickness and sub-ice shelf water column thickness
Summary
Ice-shelf disintegration is of global significance due to two important processes. Firstly, the loss of the floating portion of an ice shelf following retreat or break-up has only a minor direct effect on sea level, the removal of the buttressing effect of the ice shelf and the subsequent acceleration of the tributary ice streams can result in a significant contribution to sea level rise (e.g., Rignot et al, 2004; Scambos et al, 2004). The bathymetry model presented by Cochran and Bell (2012) exhibits over-deepening along the grounding line and two broad troughs extending from the grounding line to the ice front These features could provide conduits for oceanic circulation beneath the entire ice shelf. In order that the Cochran and Bell (2012) bathymetry map beneath Larsen C could be validated for use in oceanographic modelling, a seismic survey was undertaken in 2012/13 to obtain point measurements of ice and sub-ice shelf water cavity thickness (Fig. 2). We present the results of this survey and compare them with those obtained by inversion of the Operation IceBridge gravity data
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
