Lateral Fluxes Drive Basal Melting Beneath Thwaites Eastern Ice Shelf, West Antarctica

Peter E.D. Davis; Keith W. Nicholls; David M. Holland; Britney E. Schmidt; Peter Washam; Bieito Fernández Castro; Kiya L. Riverman; James A. Smith; Paul G.D. Anker; Andrew D. Mullen; Daniel Dichek; Elisabeth Clyne; Keith Makinson

doi:10.1029/2024GL111873

Lateral Fluxes Drive Basal Melting Beneath Thwaites Eastern Ice Shelf, West Antarctica

Peter E.D. Davis, Keith W. Nicholls, David M. Holland, Britney E. Schmidt, Peter Washam, Bieito Fernández Castro, Kiya L. Riverman, James A. Smith, Paul G.D. Anker, Andrew D. Mullen, Daniel Dichek, Elisabeth Clyne, Keith Makinson

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

Abstract

Thwaites Glacier is one of the fastest-changing ice-ocean systems in Antarctica. Basal melting beneath Thwaites' floating ice shelf, especially around pinning points and at the grounding line, sets the rate of ice loss and Thwaites' contribution to global sea-level rise. The rate of basal melting is controlled by the transport of heat into and through the ice–ocean boundary layer toward the ice base. Here we present the first turbulence observations from the grounding line of Thwaites Eastern Ice Shelf. We demonstrate that contrary to expectations, the turbulence-driven vertical flux of heat into the ice–ocean boundary layer is insufficient to sustain the basal melt rate. Instead, most of the heat required must be delivered by lateral fluxes driven by the large-scale advective circulation. Lateral processes likely dominate beneath the most unstable warm-cavity ice shelves, and thus must be fully incorporated into parameterizations of ice shelf basal melting.

Original language	English (US)
Article number	e2024GL111873
Journal	Geophysical Research Letters
Volume	52
Issue number	3
DOIs	https://doi.org/10.1029/2024GL111873
State	Published - Feb 16 2025

ASJC Scopus subject areas

Geophysics
General Earth and Planetary Sciences

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10.1029/2024GL111873

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Davis, P. E. D., Nicholls, K. W., Holland, D. M., Schmidt, B. E., Washam, P., Castro, B. F., Riverman, K. L., Smith, J. A., Anker, P. G. D., Mullen, A. D., Dichek, D., Clyne, E., & Makinson, K. (2025). Lateral Fluxes Drive Basal Melting Beneath Thwaites Eastern Ice Shelf, West Antarctica. Geophysical Research Letters, 52(3), Article e2024GL111873. https://doi.org/10.1029/2024GL111873

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title = "Lateral Fluxes Drive Basal Melting Beneath Thwaites Eastern Ice Shelf, West Antarctica",

abstract = "Thwaites Glacier is one of the fastest-changing ice-ocean systems in Antarctica. Basal melting beneath Thwaites' floating ice shelf, especially around pinning points and at the grounding line, sets the rate of ice loss and Thwaites' contribution to global sea-level rise. The rate of basal melting is controlled by the transport of heat into and through the ice–ocean boundary layer toward the ice base. Here we present the first turbulence observations from the grounding line of Thwaites Eastern Ice Shelf. We demonstrate that contrary to expectations, the turbulence-driven vertical flux of heat into the ice–ocean boundary layer is insufficient to sustain the basal melt rate. Instead, most of the heat required must be delivered by lateral fluxes driven by the large-scale advective circulation. Lateral processes likely dominate beneath the most unstable warm-cavity ice shelves, and thus must be fully incorporated into parameterizations of ice shelf basal melting.",

author = "Davis, {Peter E.D.} and Nicholls, {Keith W.} and Holland, {David M.} and Schmidt, {Britney E.} and Peter Washam and Castro, {Bieito Fern{\'a}ndez} and Riverman, {Kiya L.} and Smith, {James A.} and Anker, {Paul G.D.} and Mullen, {Andrew D.} and Daniel Dichek and Elisabeth Clyne and Keith Makinson",

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doi = "10.1029/2024GL111873",

language = "English (US)",

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T1 - Lateral Fluxes Drive Basal Melting Beneath Thwaites Eastern Ice Shelf, West Antarctica

AU - Davis, Peter E.D.

AU - Nicholls, Keith W.

AU - Holland, David M.

AU - Schmidt, Britney E.

AU - Washam, Peter

AU - Castro, Bieito Fernández

AU - Riverman, Kiya L.

AU - Smith, James A.

AU - Anker, Paul G.D.

AU - Mullen, Andrew D.

AU - Dichek, Daniel

AU - Clyne, Elisabeth

AU - Makinson, Keith

PY - 2025/2/16

Y1 - 2025/2/16

N2 - Thwaites Glacier is one of the fastest-changing ice-ocean systems in Antarctica. Basal melting beneath Thwaites' floating ice shelf, especially around pinning points and at the grounding line, sets the rate of ice loss and Thwaites' contribution to global sea-level rise. The rate of basal melting is controlled by the transport of heat into and through the ice–ocean boundary layer toward the ice base. Here we present the first turbulence observations from the grounding line of Thwaites Eastern Ice Shelf. We demonstrate that contrary to expectations, the turbulence-driven vertical flux of heat into the ice–ocean boundary layer is insufficient to sustain the basal melt rate. Instead, most of the heat required must be delivered by lateral fluxes driven by the large-scale advective circulation. Lateral processes likely dominate beneath the most unstable warm-cavity ice shelves, and thus must be fully incorporated into parameterizations of ice shelf basal melting.

AB - Thwaites Glacier is one of the fastest-changing ice-ocean systems in Antarctica. Basal melting beneath Thwaites' floating ice shelf, especially around pinning points and at the grounding line, sets the rate of ice loss and Thwaites' contribution to global sea-level rise. The rate of basal melting is controlled by the transport of heat into and through the ice–ocean boundary layer toward the ice base. Here we present the first turbulence observations from the grounding line of Thwaites Eastern Ice Shelf. We demonstrate that contrary to expectations, the turbulence-driven vertical flux of heat into the ice–ocean boundary layer is insufficient to sustain the basal melt rate. Instead, most of the heat required must be delivered by lateral fluxes driven by the large-scale advective circulation. Lateral processes likely dominate beneath the most unstable warm-cavity ice shelves, and thus must be fully incorporated into parameterizations of ice shelf basal melting.

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Lateral Fluxes Drive Basal Melting Beneath Thwaites Eastern Ice Shelf, West Antarctica

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