Current reversal leads to regime change in the Amery Ice Shelf cavity in the 21st century

Jing Jin; Antony J. Payne; Christopher Y.S. Bull

doi:10.5194/tc-19-1873-2025

Current reversal leads to regime change in the Amery Ice Shelf cavity in the 21st century

Jing Jin^*, Antony J. Payne, Christopher Y.S. Bull

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

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Abstract

The Amery Ice Shelf (AmIS), the third largest ice shelf in Antarctica, has experienced relatively low rates of basal melt during the past decades. However, it is unclear how AmIS melting will respond to a future warming climate. Here, we use a regional ocean model forced by different climate scenarios to investigate AmIS melting by 2100. The areally averaged melt rate is projected to increase from 0.7 to 8 m yr-1 in the low-emission scenario or 17 m yr-1 in the high-emission scenario in 2100. An abrupt increase in melt rate happens in the 2060s in both scenarios. The redistribution of local salinity (hence density) in front of AmIS forms a new geostrophic balance, leading to the reversal of local currents. This transforms AmIS from a cold cavity to a warm cavity and results in the jump in ice shelf melting. While the projections suggest that AmIS is unlikely to experience instability in the coming century, the high melting draws our attention to the role of oceanic processes in basal mass loss of Antarctic ice shelves in climate change.

Original language	English
Pages (from-to)	1873-1896
Number of pages	24
Journal	The Cryosphere
Volume	19
Issue number	5
DOIs	https://doi.org/10.5194/tc-19-1873-2025
Publication status	Published - 15 May 2025

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title = "Current reversal leads to regime change in the Amery Ice Shelf cavity in the 21st century",

abstract = "The Amery Ice Shelf (AmIS), the third largest ice shelf in Antarctica, has experienced relatively low rates of basal melt during the past decades. However, it is unclear how AmIS melting will respond to a future warming climate. Here, we use a regional ocean model forced by different climate scenarios to investigate AmIS melting by 2100. The areally averaged melt rate is projected to increase from 0.7 to 8 m yr-1 in the low-emission scenario or 17 m yr-1 in the high-emission scenario in 2100. An abrupt increase in melt rate happens in the 2060s in both scenarios. The redistribution of local salinity (hence density) in front of AmIS forms a new geostrophic balance, leading to the reversal of local currents. This transforms AmIS from a cold cavity to a warm cavity and results in the jump in ice shelf melting. While the projections suggest that AmIS is unlikely to experience instability in the coming century, the high melting draws our attention to the role of oceanic processes in basal mass loss of Antarctic ice shelves in climate change.",

author = "Jing Jin and Payne, \{Antony J.\} and Bull, \{Christopher Y.S.\}",

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journal = "The Cryosphere",

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T1 - Current reversal leads to regime change in the Amery Ice Shelf cavity in the 21st century

AU - Jin, Jing

AU - Payne, Antony J.

AU - Bull, Christopher Y.S.

PY - 2025/5/15

Y1 - 2025/5/15

N2 - The Amery Ice Shelf (AmIS), the third largest ice shelf in Antarctica, has experienced relatively low rates of basal melt during the past decades. However, it is unclear how AmIS melting will respond to a future warming climate. Here, we use a regional ocean model forced by different climate scenarios to investigate AmIS melting by 2100. The areally averaged melt rate is projected to increase from 0.7 to 8 m yr-1 in the low-emission scenario or 17 m yr-1 in the high-emission scenario in 2100. An abrupt increase in melt rate happens in the 2060s in both scenarios. The redistribution of local salinity (hence density) in front of AmIS forms a new geostrophic balance, leading to the reversal of local currents. This transforms AmIS from a cold cavity to a warm cavity and results in the jump in ice shelf melting. While the projections suggest that AmIS is unlikely to experience instability in the coming century, the high melting draws our attention to the role of oceanic processes in basal mass loss of Antarctic ice shelves in climate change.

AB - The Amery Ice Shelf (AmIS), the third largest ice shelf in Antarctica, has experienced relatively low rates of basal melt during the past decades. However, it is unclear how AmIS melting will respond to a future warming climate. Here, we use a regional ocean model forced by different climate scenarios to investigate AmIS melting by 2100. The areally averaged melt rate is projected to increase from 0.7 to 8 m yr-1 in the low-emission scenario or 17 m yr-1 in the high-emission scenario in 2100. An abrupt increase in melt rate happens in the 2060s in both scenarios. The redistribution of local salinity (hence density) in front of AmIS forms a new geostrophic balance, leading to the reversal of local currents. This transforms AmIS from a cold cavity to a warm cavity and results in the jump in ice shelf melting. While the projections suggest that AmIS is unlikely to experience instability in the coming century, the high melting draws our attention to the role of oceanic processes in basal mass loss of Antarctic ice shelves in climate change.

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DO - 10.5194/tc-19-1873-2025

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JO - The Cryosphere

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Current reversal leads to regime change in the Amery Ice Shelf cavity in the 21st century

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