Meteorological drivers of melt at two nearby glaciers in the McMurdo Dry Valleys of Antarctica

Marte G. Hofsteenge; Nicolas J. Cullen; Jonathan P. Conway; Carleen H. Reijmer; Michiel R. Van Den Broeke; Marwan Katurji

doi:10.1017/jog.2023.98

Meteorological drivers of melt at two nearby glaciers in the McMurdo Dry Valleys of Antarctica

Marte G. Hofsteenge^*, Nicolas J. Cullen, Jonathan P. Conway, Carleen H. Reijmer, Michiel R. Van Den Broeke, Marwan Katurji

^*Corresponding author for this work

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

Abstract

We study the meteorological drivers of melt at two glaciers in Taylor Valley, Antarctica, using 22 years of weather station observations and surface energy fluxes. The glaciers are located only 30 km apart, but have different local climates; Taylor Glacier is generally drier and windier than Commonwealth Glacier, which receives more snowfall due to its proximity to the coast. Commonwealth Glacier shows more inter-annual melt variability, explained by variable albedo due to summer snowfall events. A significant increase in surface melt at Commonwealth Glacier is associated with a decrease in summer minimum albedo. Inter-annual variability in melt at both glaciers is linked to degree-days above freezing during föhn events, occurring more frequently at Taylor Glacier. At Taylor Glacier melt occurs most often with positive air temperatures, but föhn conditions also favour sublimation, which cools the surface and prevents melt for the majority of the positive air temperatures. At Commonwealth Glacier, most of the melt instead occurs with sub-zero air temperatures, driven by strong solar radiative heating. Future melt at Taylor Glacier will likely be more sensitive to changes in föhn events, while Commonwealth Glacier will be impacted more by changes in near coastal weather, where moisture inputs can drive cloud cover, snowfall and change albedo.

Original language	English
Article number	e48
Number of pages	13
Journal	Journal of Glaciology
Volume	70
Early online date	18 Dec 2023
DOIs	https://doi.org/10.1017/jog.2023.98
Publication status	Published - 2024

Bibliographical note

Publisher Copyright:
Copyright © The Author(s), 2023. Published by Cambridge University Press on behalf of The International Glaciological Society.

Funding

The authors thank the editor and reviewer for their constructive comments. The authors wish to thank all the people who have helped maintain the instruments in the field part of the McMurdo Dry Valleys Long Term Ecological Research Project ( https://mcm.lternet.edu/ ). This research has been supported by the Antarctic Science Platform, and the Royal Society of New Zealand (grant no. ANTA1801 and RDF-UOC1701). The meteorological observations used in this study were provided by the NSF-supported McMurdo Dry Valleys Long Term Ecological Research programme (OPP-1637708).

Funders	Funder number
Royal Society Te Apārangi	RDF-UOC1701, ANTA1801

Keywords

Antarctic glaciology
energy balance
glacier meteorology
ice/atmosphere interactions
melt-surface

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meteorological-drivers-of-melt-at-two-nearby-glaciers-in-the-mcmurdo-dry-valleys-of-antarcticaFinal published version, 4.36 MBLicence: CC BY

Cite this

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title = "Meteorological drivers of melt at two nearby glaciers in the McMurdo Dry Valleys of Antarctica",

abstract = "We study the meteorological drivers of melt at two glaciers in Taylor Valley, Antarctica, using 22 years of weather station observations and surface energy fluxes. The glaciers are located only 30 km apart, but have different local climates; Taylor Glacier is generally drier and windier than Commonwealth Glacier, which receives more snowfall due to its proximity to the coast. Commonwealth Glacier shows more inter-annual melt variability, explained by variable albedo due to summer snowfall events. A significant increase in surface melt at Commonwealth Glacier is associated with a decrease in summer minimum albedo. Inter-annual variability in melt at both glaciers is linked to degree-days above freezing during f{\"o}hn events, occurring more frequently at Taylor Glacier. At Taylor Glacier melt occurs most often with positive air temperatures, but f{\"o}hn conditions also favour sublimation, which cools the surface and prevents melt for the majority of the positive air temperatures. At Commonwealth Glacier, most of the melt instead occurs with sub-zero air temperatures, driven by strong solar radiative heating. Future melt at Taylor Glacier will likely be more sensitive to changes in f{\"o}hn events, while Commonwealth Glacier will be impacted more by changes in near coastal weather, where moisture inputs can drive cloud cover, snowfall and change albedo.",

keywords = "Antarctic glaciology, energy balance, glacier meteorology, ice/atmosphere interactions, melt-surface",

author = "Hofsteenge, {Marte G.} and Cullen, {Nicolas J.} and Conway, {Jonathan P.} and Reijmer, {Carleen H.} and {Van Den Broeke}, {Michiel R.} and Marwan Katurji",

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doi = "10.1017/jog.2023.98",

language = "English",

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AB - We study the meteorological drivers of melt at two glaciers in Taylor Valley, Antarctica, using 22 years of weather station observations and surface energy fluxes. The glaciers are located only 30 km apart, but have different local climates; Taylor Glacier is generally drier and windier than Commonwealth Glacier, which receives more snowfall due to its proximity to the coast. Commonwealth Glacier shows more inter-annual melt variability, explained by variable albedo due to summer snowfall events. A significant increase in surface melt at Commonwealth Glacier is associated with a decrease in summer minimum albedo. Inter-annual variability in melt at both glaciers is linked to degree-days above freezing during föhn events, occurring more frequently at Taylor Glacier. At Taylor Glacier melt occurs most often with positive air temperatures, but föhn conditions also favour sublimation, which cools the surface and prevents melt for the majority of the positive air temperatures. At Commonwealth Glacier, most of the melt instead occurs with sub-zero air temperatures, driven by strong solar radiative heating. Future melt at Taylor Glacier will likely be more sensitive to changes in föhn events, while Commonwealth Glacier will be impacted more by changes in near coastal weather, where moisture inputs can drive cloud cover, snowfall and change albedo.

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Meteorological drivers of melt at two nearby glaciers in the McMurdo Dry Valleys of Antarctica

Abstract

Bibliographical note

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Keywords

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