Ocean mixing and heat transport processes observed under the Ross Ice Shelf control its basal melting

The stability of large Antarctic ice shelves has important implications for global sea level, sea ice area, and ocean circulation. A significant proportion of ice mass loss from these ice shelves is through ocean-driven melting which is controlled by largely unobserved oceanic thermodynamic and circ...

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Bibliographic Details
Published in:Proceedings of the National Academy of Sciences - PNAS 2020-07, Vol.117 (29), p.16799-16804
Main Authors: Stevens, Craig, Hulbe, Christina, Brewer, Mike, Stewart, Craig, Robinson, Natalie, Ohneiser, Christian, Jendersie, Stefan
Format: Article
Language:English
Subjects:
Boreholes
Boundary layers
Columnar structure
Control stability
Heat transport
Ice shelves
Land ice
Melting
Mixing processes
Ocean circulation
Ocean currents
Physical Sciences
Sea ice
Sea level
Transport processes
Water circulation
Water column
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Summary:The stability of large Antarctic ice shelves has important implications for global sea level, sea ice area, and ocean circulation. A significant proportion of ice mass loss from these ice shelves is through ocean-driven melting which is controlled by largely unobserved oceanic thermodynamic and circulatory processes in the cavity beneath the ice shelf. Here we use direct measurements to provide evidence of the changing water column structure in the cavity beneath the Ross Ice Shelf, the planet’s largest ice shelf by area. The cavity water column data exhibit both basal and benthic boundary layers, along with evidence of tidally modulated and diffusively convecting internal mixing processes. A region of thermohaline interleaving in the upper–middle water column indicates elevated diffusion and the potential to modify the cavity circulation. The measurements were recorded using the Aotearoa New Zealand Ross Ice Shelf Program hot water drill borehole melted in the central region of the shelf in December 2017 (HWD2), only the second borehole through the central region of the ice shelf, following J9 in 1977. These data, and comparison with the 1977 data, provide valuable insight into ice shelf cavity circulation and aid understanding of the evolution of the presently stable Ross Ice Shelf.
ISSN:0027-8424
1091-6490
DOI:10.1073/pnas.1910760117