The system of atmosphere, land, ice and ocean in the region near the 79N Glacier in northeast Greenland: synthesis and key findings from the Greenland Ice Sheet-Ocean Interaction (GROCE) experiment

Kanzow T, Humbert A, Mölg T, Scheinert M, Braun M, Burchard H, Doglioni F, Hochreuther P, Horwath M, Huhn O, Kappelsberger M, Kusche J, Loebel E, Lutz K, Marzeion B, Mcpherson R, Mohammadi-Aragh M, Möller M, Pickler C, Reinert M, Rhein M, Rückamp M, Schaffer J, Shafeeque M, Stolzenberger S, Timmermann R, Turton J, Wekerle C, Zeising O (2025)

Publication Language: English

Publication Type: Journal article

Publication year: 2025

Journal

Book Volume: 19

Pages Range: 1789-1824

Journal Issue: 5

DOI: 10.5194/tc-19-1789-2025

Abstract

The Greenland Ice Sheet has steadily lost mass over the past decades, presently representing the second-largest single contributor to global sea-level rise. In line with the rest of the Greenland Ice Sheet, the glaciers draining the northeast Greenland ice stream have been observed to retreat and thin. Here, we present a comprehensive study of processes affecting and being affected by the mass balance of marine-terminating and peripheral glaciers in northeast (NE) Greenland. Our focus is on the 79N Glacier (79NG), which hosts Greenland's largest floating ice tongue. We provide new insight into the ice surface melt, the ice mass balance, glacier dynamics, the regional solid Earth response, the ocean-driven basal melt and the consequences of meltwater discharge into the ocean. Our study is based on field observations, remote sensing and simulations with numerical models of different complexity, most of them originating from the Greenland Ice Sheet-Ocean Interaction (GROCE) experiment. We find the overall negative climatic mass balance of 79NG to co-vary with summertime volumes of supraglacial lakes and show that the spatial pattern of the overall negative ice mass balance for NE Greenland is mirrored by the pattern of glacial-isostatic adjustment. We find near-coastal mass losses of both marine-terminating and peripheral glaciers in NE Greenland to be of a similar magnitude in the last decade. In contrast to the neighboring Zachariæ Isstrøm, 79NG - despite experiencing massive thinning of the floating tongue - has resisted an acceleration of ice discharge across the grounding line due to buttressing imposed by lateral friction of the 70 km long ice tongue in the narrow glacial fjord. Observations and models employed in this study are consistent in terms of melt rates occurring below the floating ice tongue. Our results suggest that the multidecadal warming of Atlantic Intermediate Water flowing into the cavity below the ice tongue - supplied by the recirculating branch of the West Spitsbergen Current in Fram Strait - is the main driver of the recent major increase in basal melt rates. We find that the meltwater leaving the cavity toward the ocean at subsurface levels quickly dilutes on the wide shelf. The study concludes by summarizing important estimates of changes to the state of the atmosphere, ice, land and ocean domains.

Authors with CRIS profile

Involved external institutions

Alfred-Wegener-Institut Helmholtz-Zentrum für Polar- und Meeresforschung (AWI) Germany (DE) Technische Universität Dresden Germany (DE) Leibniz-Institut für Ostseeforschung / Leibniz Institute for Baltic Sea Research Germany (DE) Universität Bremen Germany (DE) Rheinische Friedrich-Wilhelms-Universität Bonn Germany (DE)

How to cite

APA:

Kanzow, T., Humbert, A., Mölg, T., Scheinert, M., Braun, M., Burchard, H.,... Zeising, O. (2025). The system of atmosphere, land, ice and ocean in the region near the 79N Glacier in northeast Greenland: synthesis and key findings from the Greenland Ice Sheet-Ocean Interaction (GROCE) experiment. Cryosphere, 19(5), 1789-1824. https://doi.org/10.5194/tc-19-1789-2025

MLA:

Kanzow, Torsten, et al. "The system of atmosphere, land, ice and ocean in the region near the 79N Glacier in northeast Greenland: synthesis and key findings from the Greenland Ice Sheet-Ocean Interaction (GROCE) experiment." Cryosphere 19.5 (2025): 1789-1824.

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