Calving of Ross Ice Shelf from wave erosion and hydrostatic stresses

Ice shelf calving constitutes roughly half of the total mass loss from the Antarctic ice sheet. Although much attention is paid to calving of giant tabular icebergs, these events are relatively rare. More frequent, smaller-scale calving events likely play an important role in the ice shelf frontal d...

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Bibliographic Details
Main Authors: Sartore, Nicolas B., Wagner, Till J. W., Siegfried, Matthew R., Pujara, Nimish, Zoet, Lucas K.
Format: Article in Journal/Newspaper
Language:English
Published: Copernicus Publications 2024
Subjects:
article
Verlagsveröffentlichung
Antarc*
Antarctic
Ice Sheet
Ice Shelf
Iceberg*
Ross Ice Shelf
Online Access:https://doi.org/10.5194/egusphere-2024-571
https://noa.gwlb.de/receive/cop_mods_00072540
https://noa.gwlb.de/servlets/MCRFileNodeServlet/cop_derivate_00070747/egusphere-2024-571.pdf
https://egusphere.copernicus.org/preprints/2024/egusphere-2024-571/egusphere-2024-571.pdf
Description
Summary:Ice shelf calving constitutes roughly half of the total mass loss from the Antarctic ice sheet. Although much attention is paid to calving of giant tabular icebergs, these events are relatively rare. More frequent, smaller-scale calving events likely play an important role in the ice shelf frontal dynamics. Here, we investigate the role of bending stresses at the ice shelf front in driving calving on the scale 100 m – 1 km, perpendicular to the ice edge. We focus in particular on how buoyant underwater "feet" that protrude beyond the above-water ice cliff may cause tensile stresses at the base of the ice and ultimately lead to fracture. Indirect and anecdotal observations of such feet at the Ross Ice Shelf front suggest that this process may be widespread. We consider satellite observations, together with an elastic beam model and a parameterization of frontal wave erosion to estimate the size and frequency of such calving events. Our results suggest that foot-induced mass loss at Ross Ice Shelf may cause up to 25 % of the total frontal ablation. However, stresses induced through this process are likely not sufficient to initiate crevassing but rather act to propagate existing crevasses. In addition, the relatively strong ice thickness dependence of the frontal uplift suggests an important role for internal bending moments due to temperature gradients in the ice. The highly variable environment, irregularity of pre-existing crevasse spacing, and complex rheology of the ice continue to pose challenges in better constraining the drivers behind the observed deformations and resulting calving rates.

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