Ice-Front Retreat Controls on Ocean Dynamics Under Larsen C Ice Shelf, Antarctica

M. Poinelli; Y. Nakayama; E. Larour; M. Vizcaino; R. Riva

doi:10.1029/2023GL104588

Ice-Front Retreat Controls on Ocean Dynamics Under Larsen C Ice Shelf, Antarctica

M. Poinelli^*, Y. Nakayama, E. Larour, M. Vizcaino, R. Riva

^*Corresponding author for this work

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Abstract

Iceberg A-68 separated from the Larsen C Ice Shelf in July 2017 and the impact of this event on the local ocean circulation has yet to be assessed. Here, we conduct numerical simulations of ocean dynamics near and below the ice shelf pre- and post-calving. Results agree with in situ and remote observations of the area as they indicate that basal melt is primarily controlled by wintertime sea-ice formation, which in turn produces High Salinity Shelf Water (HSSW). After the calving event, we simulate a 50% increase in HSSW intrusion under the ice shelf, enhancing ocean heat delivery by 30%. This results in doubling of the melt rate under Gipps Ice Rise, suggesting a positive feedback for further retreat that could destabilize the Larsen C Ice Shelf. Assessing the impact of ice-front retreat on the heat delivery under the ice is crucial to better understand ice-shelf dynamics in a warming environment.

Original language	English
Article number	e2023GL104588
Number of pages	9
Journal	Geophysical Research Letters
Volume	50
Issue number	18
DOIs	https://doi.org/10.1029/2023GL104588
Publication status	Published - 2023

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Ice-Front Retreat Controls on Ocean Dynamics Under Larsen C Ice Shelf, AntarcticaFinal published version, 6.21 MBLicence: CC BY

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title = "Ice-Front Retreat Controls on Ocean Dynamics Under Larsen C Ice Shelf, Antarctica",

abstract = "Iceberg A-68 separated from the Larsen C Ice Shelf in July 2017 and the impact of this event on the local ocean circulation has yet to be assessed. Here, we conduct numerical simulations of ocean dynamics near and below the ice shelf pre- and post-calving. Results agree with in situ and remote observations of the area as they indicate that basal melt is primarily controlled by wintertime sea-ice formation, which in turn produces High Salinity Shelf Water (HSSW). After the calving event, we simulate a 50% increase in HSSW intrusion under the ice shelf, enhancing ocean heat delivery by 30%. This results in doubling of the melt rate under Gipps Ice Rise, suggesting a positive feedback for further retreat that could destabilize the Larsen C Ice Shelf. Assessing the impact of ice-front retreat on the heat delivery under the ice is crucial to better understand ice-shelf dynamics in a warming environment.",

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T1 - Ice-Front Retreat Controls on Ocean Dynamics Under Larsen C Ice Shelf, Antarctica

AU - Poinelli, M.

AU - Nakayama, Y.

AU - Larour, E.

AU - Vizcaino, M.

AU - Riva, R.

PY - 2023

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N2 - Iceberg A-68 separated from the Larsen C Ice Shelf in July 2017 and the impact of this event on the local ocean circulation has yet to be assessed. Here, we conduct numerical simulations of ocean dynamics near and below the ice shelf pre- and post-calving. Results agree with in situ and remote observations of the area as they indicate that basal melt is primarily controlled by wintertime sea-ice formation, which in turn produces High Salinity Shelf Water (HSSW). After the calving event, we simulate a 50% increase in HSSW intrusion under the ice shelf, enhancing ocean heat delivery by 30%. This results in doubling of the melt rate under Gipps Ice Rise, suggesting a positive feedback for further retreat that could destabilize the Larsen C Ice Shelf. Assessing the impact of ice-front retreat on the heat delivery under the ice is crucial to better understand ice-shelf dynamics in a warming environment.

AB - Iceberg A-68 separated from the Larsen C Ice Shelf in July 2017 and the impact of this event on the local ocean circulation has yet to be assessed. Here, we conduct numerical simulations of ocean dynamics near and below the ice shelf pre- and post-calving. Results agree with in situ and remote observations of the area as they indicate that basal melt is primarily controlled by wintertime sea-ice formation, which in turn produces High Salinity Shelf Water (HSSW). After the calving event, we simulate a 50% increase in HSSW intrusion under the ice shelf, enhancing ocean heat delivery by 30%. This results in doubling of the melt rate under Gipps Ice Rise, suggesting a positive feedback for further retreat that could destabilize the Larsen C Ice Shelf. Assessing the impact of ice-front retreat on the heat delivery under the ice is crucial to better understand ice-shelf dynamics in a warming environment.

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Ice-Front Retreat Controls on Ocean Dynamics Under Larsen C Ice Shelf, Antarctica

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Ocean Dynamics and Ice Fractures: Insights from Earth and Beyond

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