Peak refreezing in the Greenland firn layer under future warming scenarios

Brice Noël; Jan T.M. Lenaerts; William H. Lipscomb; Katherine Thayer-Calder; Michiel R. van den Broeke

doi:10.1038/s41467-022-34524-x

Peak refreezing in the Greenland firn layer under future warming scenarios

Brice Noël, Jan T.M. Lenaerts, William H. Lipscomb, Katherine Thayer-Calder, Michiel R. van den Broeke

Paleo and Polar Climate

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17 Scopus citations

Abstract

Firn (compressed snow) covers approximately 90% of the Greenland ice sheet (GrIS) and currently retains about half of rain and meltwater through refreezing, reducing runoff and subsequent mass loss. The loss of firn could mark a tipping point for sustained GrIS mass loss, since decades to centuries of cold summers would be required to rebuild the firn buffer. Here we estimate the warming required for GrIS firn to reach peak refreezing, using 51 climate simulations statistically downscaled to 1 km resolution, that project the long-term firn layer evolution under multiple emission scenarios (1850–2300). We predict that refreezing stabilises under low warming scenarios, whereas under extreme warming, refreezing could peak and permanently decline starting in southwest Greenland by 2100, and further expanding GrIS-wide in the early 22ⁿ^d century. After passing this peak, the GrIS contribution to global sea level rise would increase over twenty-fold compared to the last three decades.

Original language	English
Article number	6870
Journal	Nature Communications
Volume	13
Issue number	1
DOIs	https://doi.org/10.1038/s41467-022-34524-x
State	Published - Dec 2022

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title = "Peak refreezing in the Greenland firn layer under future warming scenarios",

abstract = "Firn (compressed snow) covers approximately 90\% of the Greenland ice sheet (GrIS) and currently retains about half of rain and meltwater through refreezing, reducing runoff and subsequent mass loss. The loss of firn could mark a tipping point for sustained GrIS mass loss, since decades to centuries of cold summers would be required to rebuild the firn buffer. Here we estimate the warming required for GrIS firn to reach peak refreezing, using 51 climate simulations statistically downscaled to 1 km resolution, that project the long-term firn layer evolution under multiple emission scenarios (1850–2300). We predict that refreezing stabilises under low warming scenarios, whereas under extreme warming, refreezing could peak and permanently decline starting in southwest Greenland by 2100, and further expanding GrIS-wide in the early 22nd century. After passing this peak, the GrIS contribution to global sea level rise would increase over twenty-fold compared to the last three decades.",

author = "Brice No{\"e}l and Lenaerts, \{Jan T.M.\} and Lipscomb, \{William H.\} and Katherine Thayer-Calder and \{van den Broeke\}, \{Michiel R.\}",

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doi = "10.1038/s41467-022-34524-x",

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volume = "13",

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T1 - Peak refreezing in the Greenland firn layer under future warming scenarios

AU - Noël, Brice

AU - Lenaerts, Jan T.M.

AU - Lipscomb, William H.

AU - Thayer-Calder, Katherine

AU - van den Broeke, Michiel R.

PY - 2022/12

Y1 - 2022/12

N2 - Firn (compressed snow) covers approximately 90% of the Greenland ice sheet (GrIS) and currently retains about half of rain and meltwater through refreezing, reducing runoff and subsequent mass loss. The loss of firn could mark a tipping point for sustained GrIS mass loss, since decades to centuries of cold summers would be required to rebuild the firn buffer. Here we estimate the warming required for GrIS firn to reach peak refreezing, using 51 climate simulations statistically downscaled to 1 km resolution, that project the long-term firn layer evolution under multiple emission scenarios (1850–2300). We predict that refreezing stabilises under low warming scenarios, whereas under extreme warming, refreezing could peak and permanently decline starting in southwest Greenland by 2100, and further expanding GrIS-wide in the early 22nd century. After passing this peak, the GrIS contribution to global sea level rise would increase over twenty-fold compared to the last three decades.

AB - Firn (compressed snow) covers approximately 90% of the Greenland ice sheet (GrIS) and currently retains about half of rain and meltwater through refreezing, reducing runoff and subsequent mass loss. The loss of firn could mark a tipping point for sustained GrIS mass loss, since decades to centuries of cold summers would be required to rebuild the firn buffer. Here we estimate the warming required for GrIS firn to reach peak refreezing, using 51 climate simulations statistically downscaled to 1 km resolution, that project the long-term firn layer evolution under multiple emission scenarios (1850–2300). We predict that refreezing stabilises under low warming scenarios, whereas under extreme warming, refreezing could peak and permanently decline starting in southwest Greenland by 2100, and further expanding GrIS-wide in the early 22nd century. After passing this peak, the GrIS contribution to global sea level rise would increase over twenty-fold compared to the last three decades.

UR - https://www.scopus.com/pages/publications/85141688171

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DO - 10.1038/s41467-022-34524-x

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JO - Nature Communications

JF - Nature Communications

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ER -

Peak refreezing in the Greenland firn layer under future warming scenarios

Abstract

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