Observations of submesoscale eddy-driven heat transport at an ice shelf calving front
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Title
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Observations of submesoscale eddy-driven heat transport at an ice shelf calving front
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Other Titles
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빙붕 끝 부분에서 일어나는 소규모 소용돌이에 의한 해양 열전달 관측
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Authors
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Drew M. Friedrichs
Jasmin B. T. McInerney
Holly J. Oldroyd
Lee, Won Sang
Yun, Sukyoung
Seung-Tae Yoon
Craig L. Stevens
Christopher J. Zappa
Christine F. Dow
Derek Mueller
Oscar Sepulveda Steiner
Alexander L. Forrest
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Keywords
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Antarctica; Eddy; Ice Shelf; Ocean Heat Transport; Sea Level Rise; Underwater Robotics
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Issue Date
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2022
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Citation
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Drew M. Friedrichs, et al. 2022. "Observations of submesoscale eddy-driven heat transport at an ice shelf calving front". COMMUNICATIONS EARTH & ENVIRONMENT, 3(1): 1-9.
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Abstract
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Antarctica’s ice shelves buttress the continent’s terrestrial ice, helping slow the loss of grounded ice into the ocean and limiting sea level rise. Ice-ocean interaction plays a critical role in ice shelf stability by driving basal melt rates. Consequently, improved prediction of the future state of ice shelves lies in understanding the coastal ocean mechanics that deliver heat to their cavities. Here, we present autonomous glider-based observations of a coherent structure at the calving front of a cold-water cavity ice shelf (Nansen Ice Shelf, East Antarctica). This ~10 km-wide eddy dominated the local ocean circulation in the austral summer of 2018/2019, promoting an upwelling of cold ice shelf water and a deepening of warm surface water. Microstructure turbulence measurements show a resulting maximum vertical heat transport of 10Wm?2 at depths equivalent to the ice shelf draft. Similar eddy-driven heat transport further into the ice shelf cavity would support enhanced summertime melt in regions of shallower ice draft.
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URI
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https://repository.kopri.re.kr/handle/201206/15404
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DOI
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http://dx.doi.org/10.1038/s43247-022-00460-3
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Type
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Article
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Station
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Araon
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Indexed
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SCIE
- Appears in Collections
- 2022-2023, Land-Ice/Ocean Network Exploration with Semiautonomous Systems: Thwaites Glacier (LIONESS/TG) - Toward understanding the fate of the Thwaites Glacier by abrupt collapse and its impact on global sea level changes - (22-23) / Lee, Won Sang (PM22020)
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