Suppressed basal melting in the eastern Thwaites Glacier grounding zone

Peter E. D. Davis; Keith W. Nicholls; David M. Holland; Britney E. Schmidt; Peter Washam; Kiya L. Riverman; Robert J. Arthern; Irena Vaňková; Clare Eayrs; James A. Smith; Paul G. D. Anker; Andrew D. Mullen; Daniel Dichek; Justin D. Lawrence; Matthew M. Meister; Elisabeth Clyne; Aurora Basinski-Ferris; Eric Rignot; Bastien Y. Queste; Lars Boehme; Karen J. Heywood; Sridhar Anandakrishnan; Keith Makinson

doi:10.1038/s41586-022-05586-0

Suppressed basal melting in the eastern Thwaites Glacier grounding zone

Peter E. D. Davis, Keith W. Nicholls, David M. Holland, Britney E. Schmidt, Peter Washam, Kiya L. Riverman, Robert J. Arthern, Irena Vaňková, Clare Eayrs, James A. Smith, Paul G. D. Anker, Andrew D. Mullen, Daniel Dichek, Justin D. Lawrence, Matthew M. Meister, Elisabeth Clyne, Aurora Basinski-Ferris, Eric Rignot, Bastien Y. Queste, Lars BoehmeKaren J. Heywood, Sridhar Anandakrishnan, Keith Makinson

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

14 Citations (Scopus)

Abstract

Thwaites Glacier is one of the fastest-changing ice–ocean systems in Antarctica ^1–3. Much of the ice sheet within the catchment of Thwaites Glacier is grounded below sea level on bedrock that deepens inland ⁴, making it susceptible to rapid and irreversible ice loss that could raise the global sea level by more than half a metre ^2,3,5. The rate and extent of ice loss, and whether it proceeds irreversibly, are set by the ocean conditions and basal melting within the grounding-zone region where Thwaites Glacier first goes afloat ^3,6, both of which are largely unknown. Here we show—using observations from a hot-water-drilled access hole—that the grounding zone of Thwaites Eastern Ice Shelf (TEIS) is characterized by a warm and highly stable water column with temperatures substantially higher than the in situ freezing point. Despite these warm conditions, low current speeds and strong density stratification in the ice–ocean boundary layer actively restrict the vertical mixing of heat towards the ice base ^7,8, resulting in strongly suppressed basal melting. Our results demonstrate that the canonical model of ice-shelf basal melting used to generate sea-level projections cannot reproduce observed melt rates beneath this critically important glacier, and that rapid and possibly unstable grounding-line retreat may be associated with relatively modest basal melt rates.

Original language	English
Pages (from-to)	479–485
Number of pages	7
Journal	Nature
Volume	614
Issue number	7948
Early online date	15 Feb 2023
DOIs	https://doi.org/10.1038/s41586-022-05586-0
Publication status	Published - 16 Feb 2023

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Davies_etal_2023_NatureFinal published version, 14 MBLicence: CC BY

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Davis, P. E. D., Nicholls, K. W., Holland, D. M., Schmidt, B. E., Washam, P., Riverman, K. L., Arthern, R. J., Vaňková, I., Eayrs, C., Smith, J. A., Anker, P. G. D., Mullen, A. D., Dichek, D., Lawrence, J. D., Meister, M. M., Clyne, E., Basinski-Ferris, A., Rignot, E., Queste, B. Y., ... Makinson, K. (2023). Suppressed basal melting in the eastern Thwaites Glacier grounding zone. Nature, 614(7948), 479–485. https://doi.org/10.1038/s41586-022-05586-0

Davis, Peter E. D. ; Nicholls, Keith W. ; Holland, David M. ; Schmidt, Britney E. ; Washam, Peter ; Riverman, Kiya L. ; Arthern, Robert J. ; Vaňková, Irena ; Eayrs, Clare ; Smith, James A. ; Anker, Paul G. D. ; Mullen, Andrew D. ; Dichek, Daniel ; Lawrence, Justin D. ; Meister, Matthew M. ; Clyne, Elisabeth ; Basinski-Ferris, Aurora ; Rignot, Eric ; Queste, Bastien Y. ; Boehme, Lars ; Heywood, Karen J. ; Anandakrishnan, Sridhar ; Makinson, Keith. / Suppressed basal melting in the eastern Thwaites Glacier grounding zone. In: Nature. 2023 ; Vol. 614, No. 7948. pp. 479–485.

@article{83dc8a9f544a465a8175ef13bf8690a0,

title = "Suppressed basal melting in the eastern Thwaites Glacier grounding zone",

abstract = "Thwaites Glacier is one of the fastest-changing ice–ocean systems in Antarctica 1–3. Much of the ice sheet within the catchment of Thwaites Glacier is grounded below sea level on bedrock that deepens inland 4, making it susceptible to rapid and irreversible ice loss that could raise the global sea level by more than half a metre 2,3,5. The rate and extent of ice loss, and whether it proceeds irreversibly, are set by the ocean conditions and basal melting within the grounding-zone region where Thwaites Glacier first goes afloat 3,6, both of which are largely unknown. Here we show—using observations from a hot-water-drilled access hole—that the grounding zone of Thwaites Eastern Ice Shelf (TEIS) is characterized by a warm and highly stable water column with temperatures substantially higher than the in situ freezing point. Despite these warm conditions, low current speeds and strong density stratification in the ice–ocean boundary layer actively restrict the vertical mixing of heat towards the ice base 7,8, resulting in strongly suppressed basal melting. Our results demonstrate that the canonical model of ice-shelf basal melting used to generate sea-level projections cannot reproduce observed melt rates beneath this critically important glacier, and that rapid and possibly unstable grounding-line retreat may be associated with relatively modest basal melt rates. ",

author = "Davis, {Peter E. D.} and Nicholls, {Keith W.} and Holland, {David M.} and Schmidt, {Britney E.} and Peter Washam and Riverman, {Kiya L.} and Arthern, {Robert J.} and Irena Va{\v n}kov{\'a} and Clare Eayrs and Smith, {James A.} and Anker, {Paul G. D.} and Mullen, {Andrew D.} and Daniel Dichek and Lawrence, {Justin D.} and Meister, {Matthew M.} and Elisabeth Clyne and Aurora Basinski-Ferris and Eric Rignot and Queste, {Bastien Y.} and Lars Boehme and Heywood, {Karen J.} and Sridhar Anandakrishnan and Keith Makinson",

note = "Acknowledgements: This work is from the MELT project, a component of the International Thwaites Glacier Collaboration (ITGC). Support from the National Science Foundation (NSF, grant no. 1739003) and the Natural Environment Research Council (NERC, grant no. NE/S006656/1). Logistics provided by NSF U.S. Antarctic Program and NERC British Antarctic Survey. The ship-based CTD data were supported by the ITGC TARSAN project (NERC grant nos. NE/S006419/1 and NE/S006591/1; NSF grant no. 1929991). ITGC contribution no. ITGC 047. Data availability: The CTD data are available from the UK Polar Data Centre (https://doi.org/10.5285/97204415-683f-4d55-8b38-a2700fa94efe). The mooring data are available from the UK Polar Data Centre (https://doi.org/10.5285/4ffad557-1c3c-4ea7-a73d-6d782331b08a). The ApRES basal melt-rate data are available from the UK Polar Data Centre (https://doi.org/10.5285/B81BFF87-3429-4754-B4B5-C6B58198E744). The Icefin data are available from the United States Antarctic Program Data Center (https://doi.org/10.15784/601618). Code availability: The MATLAB Gibbs-SeaWater (GSW) Oceanographic Toolbox for TEOS-10 (v3.06) is available at: https://www.teos-10.org/software.htm. The custom MATLAB (R2021a) code and additional materials and libraries required to process the data and generate the figures in the article are available on request from the corresponding author.",

year = "2023",

month = feb,

day = "16",

doi = "10.1038/s41586-022-05586-0",

language = "English",

volume = "614",

pages = "479–485",

journal = "Nature",

issn = "0028-0836",

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Davis, PED, Nicholls, KW, Holland, DM, Schmidt, BE, Washam, P, Riverman, KL, Arthern, RJ, Vaňková, I, Eayrs, C, Smith, JA, Anker, PGD, Mullen, AD, Dichek, D, Lawrence, JD, Meister, MM, Clyne, E, Basinski-Ferris, A, Rignot, E, Queste, BY, Boehme, L, Heywood, KJ, Anandakrishnan, S & Makinson, K 2023, 'Suppressed basal melting in the eastern Thwaites Glacier grounding zone', Nature, vol. 614, no. 7948, pp. 479–485. https://doi.org/10.1038/s41586-022-05586-0

Suppressed basal melting in the eastern Thwaites Glacier grounding zone. / Davis, Peter E. D.; Nicholls, Keith W.; Holland, David M.; Schmidt, Britney E.; Washam, Peter; Riverman, Kiya L.; Arthern, Robert J.; Vaňková, Irena; Eayrs, Clare; Smith, James A.; Anker, Paul G. D.; Mullen, Andrew D.; Dichek, Daniel; Lawrence, Justin D.; Meister, Matthew M.; Clyne, Elisabeth; Basinski-Ferris, Aurora; Rignot, Eric; Queste, Bastien Y.; Boehme, Lars; Heywood, Karen J.; Anandakrishnan, Sridhar; Makinson, Keith.

In: Nature, Vol. 614, No. 7948, 16.02.2023, p. 479–485.

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

TY - JOUR

T1 - Suppressed basal melting in the eastern Thwaites Glacier grounding zone

AU - Davis, Peter E. D.

AU - Nicholls, Keith W.

AU - Holland, David M.

AU - Schmidt, Britney E.

AU - Washam, Peter

AU - Riverman, Kiya L.

AU - Arthern, Robert J.

AU - Vaňková, Irena

AU - Eayrs, Clare

AU - Smith, James A.

AU - Anker, Paul G. D.

AU - Mullen, Andrew D.

AU - Dichek, Daniel

AU - Lawrence, Justin D.

AU - Meister, Matthew M.

AU - Clyne, Elisabeth

AU - Basinski-Ferris, Aurora

AU - Rignot, Eric

AU - Queste, Bastien Y.

AU - Boehme, Lars

AU - Heywood, Karen J.

AU - Anandakrishnan, Sridhar

AU - Makinson, Keith

N1 - Acknowledgements: This work is from the MELT project, a component of the International Thwaites Glacier Collaboration (ITGC). Support from the National Science Foundation (NSF, grant no. 1739003) and the Natural Environment Research Council (NERC, grant no. NE/S006656/1). Logistics provided by NSF U.S. Antarctic Program and NERC British Antarctic Survey. The ship-based CTD data were supported by the ITGC TARSAN project (NERC grant nos. NE/S006419/1 and NE/S006591/1; NSF grant no. 1929991). ITGC contribution no. ITGC 047. Data availability: The CTD data are available from the UK Polar Data Centre (https://doi.org/10.5285/97204415-683f-4d55-8b38-a2700fa94efe). The mooring data are available from the UK Polar Data Centre (https://doi.org/10.5285/4ffad557-1c3c-4ea7-a73d-6d782331b08a). The ApRES basal melt-rate data are available from the UK Polar Data Centre (https://doi.org/10.5285/B81BFF87-3429-4754-B4B5-C6B58198E744). The Icefin data are available from the United States Antarctic Program Data Center (https://doi.org/10.15784/601618). Code availability: The MATLAB Gibbs-SeaWater (GSW) Oceanographic Toolbox for TEOS-10 (v3.06) is available at: https://www.teos-10.org/software.htm. The custom MATLAB (R2021a) code and additional materials and libraries required to process the data and generate the figures in the article are available on request from the corresponding author.

PY - 2023/2/16

Y1 - 2023/2/16

N2 - Thwaites Glacier is one of the fastest-changing ice–ocean systems in Antarctica 1–3. Much of the ice sheet within the catchment of Thwaites Glacier is grounded below sea level on bedrock that deepens inland 4, making it susceptible to rapid and irreversible ice loss that could raise the global sea level by more than half a metre 2,3,5. The rate and extent of ice loss, and whether it proceeds irreversibly, are set by the ocean conditions and basal melting within the grounding-zone region where Thwaites Glacier first goes afloat 3,6, both of which are largely unknown. Here we show—using observations from a hot-water-drilled access hole—that the grounding zone of Thwaites Eastern Ice Shelf (TEIS) is characterized by a warm and highly stable water column with temperatures substantially higher than the in situ freezing point. Despite these warm conditions, low current speeds and strong density stratification in the ice–ocean boundary layer actively restrict the vertical mixing of heat towards the ice base 7,8, resulting in strongly suppressed basal melting. Our results demonstrate that the canonical model of ice-shelf basal melting used to generate sea-level projections cannot reproduce observed melt rates beneath this critically important glacier, and that rapid and possibly unstable grounding-line retreat may be associated with relatively modest basal melt rates.

AB - Thwaites Glacier is one of the fastest-changing ice–ocean systems in Antarctica 1–3. Much of the ice sheet within the catchment of Thwaites Glacier is grounded below sea level on bedrock that deepens inland 4, making it susceptible to rapid and irreversible ice loss that could raise the global sea level by more than half a metre 2,3,5. The rate and extent of ice loss, and whether it proceeds irreversibly, are set by the ocean conditions and basal melting within the grounding-zone region where Thwaites Glacier first goes afloat 3,6, both of which are largely unknown. Here we show—using observations from a hot-water-drilled access hole—that the grounding zone of Thwaites Eastern Ice Shelf (TEIS) is characterized by a warm and highly stable water column with temperatures substantially higher than the in situ freezing point. Despite these warm conditions, low current speeds and strong density stratification in the ice–ocean boundary layer actively restrict the vertical mixing of heat towards the ice base 7,8, resulting in strongly suppressed basal melting. Our results demonstrate that the canonical model of ice-shelf basal melting used to generate sea-level projections cannot reproduce observed melt rates beneath this critically important glacier, and that rapid and possibly unstable grounding-line retreat may be associated with relatively modest basal melt rates.

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DO - 10.1038/s41586-022-05586-0

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SP - 479

EP - 485

JO - Nature

JF - Nature

SN - 0028-0836

IS - 7948

ER -

Suppressed basal melting in the eastern Thwaites Glacier grounding zone

Abstract

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NSFPLR-NERC: Thwaites-Amundsen Regional Survey and Network (TARSAN). Integrating Atmosphere-Ice-Ocean Processes affecting the Sub-Ice-Shelf Environment.

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Suppressed basal melting in the eastern Thwaites Glacier grounding zone

Abstract

Access to Document

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NSFPLR-NERC: Thwaites-Amundsen Regional Survey and Network (TARSAN). Integrating Atmosphere-Ice-Ocean Processes affecting the Sub-Ice-Shelf Environment.

Cite this