Coupled ice shelf-ocean modeling and complex grounding line retreat from a seabed ridge

Recent observations and modeling work have shown a complex mechanical coupling between Antarctica's floating ice shelves and the adjacent grounded ice sheet. A prime example is Pine Island Glacier, West Antarctica, which has a strong negative mass balance caused by a recent increase in ocean-in...

Full description

Bibliographic Details
Published in:Journal of Geophysical Research: Earth Surface
Main Authors: de Rydt, Jan, Gudmundsson, Hilmar
Format: Article in Journal/Newspaper
Language:unknown
Published: Wiley-Blackwell 2016
Subjects:
F800 Physical and Terrestrial Geographical and Environmental Sciences
Pine Island Glacier
West Antarctica
Antarc*
Antarctica
Ice Sheet
Ice Shelf
Ice Shelves
Pine Island
Online Access:https://nrl.northumbria.ac.uk/id/eprint/34666/
https://doi.org/10.1002/2015JF003791
Description
Summary:Recent observations and modeling work have shown a complex mechanical coupling between Antarctica's floating ice shelves and the adjacent grounded ice sheet. A prime example is Pine Island Glacier, West Antarctica, which has a strong negative mass balance caused by a recent increase in ocean-induced melting of its ice shelf. The mass loss coincides with the retreat of the grounding line from a seabed ridge, on which it was at least partly grounded until the 1970s. At present, it is unclear what has caused the onset of this retreat and how feedback mechanisms between the ocean and ice shelf geometry have influenced the ice dynamics. To address these questions, we present the first results from an offline coupling between a state-of-the-art shallow-ice flow model with grounding line resolving capabilities and a three-dimensional ocean general circulation model with a static implementation of the ice shelf. A series of idealized experiments simulate the retreat from a seabed ridge in response to changes in the ocean forcing, and we show that the retreat becomes irreversible after 20 years of warm ocean conditions. A comparison to experiments with a simple depth-dependent melt rate parameterization demonstrates that such parameterizations are unable to capture the details of the retreat process, and they overestimate mass loss by more than 40% over a 50 year timescale.

Similar Items