Air Temperature Distribution and Energy-balance Modelling of a Debris-covered Glacier

Near-surface air temperature is an important determinant of the surface energy balance of glaciers and is often represented by a constant linear temperature gradients (TGs) in models. Spatiotemporal variability in 2 m air temperature was measured across the debris-covered Miage Glacier, Italy, over...

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Published in:Journal of Glaciology
Main Authors: Shaw, T.E., Brock, B.W., Fyffe, Catriona, Pellicciotti, F., Rutter, N., Diotri, F.
Format: Article in Journal/Newspaper
Language:English
Published: Cambridge University Press 2016
Subjects:
GB Physical geography
Journal of Glaciology
Online Access:http://eprints.worc.ac.uk/4761/
https://eprints.worc.ac.uk/4761/1/Shaw%20et%20al.,%202016.pdf
https://doi.org/10.1017/jog.2016.31
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author Shaw, T.E.
Brock, B.W.
Fyffe, Catriona
Pellicciotti, F.
Rutter, N.
Diotri, F.
author_facet Shaw, T.E.
Brock, B.W.
Fyffe, Catriona
Pellicciotti, F.
Rutter, N.
Diotri, F.
author_sort Shaw, T.E.
collection University of Worcester: Worcester Research and Publications
container_issue 231
container_start_page 185
container_title Journal of Glaciology
container_volume 62
description Near-surface air temperature is an important determinant of the surface energy balance of glaciers and is often represented by a constant linear temperature gradients (TGs) in models. Spatiotemporal variability in 2 m air temperature was measured across the debris-covered Miage Glacier, Italy, over an 89 d period during the 2014 ablation season using a network of 19 stations. Air temperature was found to be strongly dependent upon elevation for most stations, even under varying meteorological conditions and at different times of day, and its spatial variability was well explained by a locally derived mean linear TG (MG–TG) of −0.0088°C m−1. However, local temperature depressions occurred over areas of very thin or patchy debris cover. The MG–TG, together with other air TGs, extrapolated from both on- and off-glacier sites, were applied in a distributed energy-balance model. Compared with piecewise air temperature extrapolation from all on-glacier stations, modelled ablation, using the MG–TG, increased by <1%, increasing to >4% using the environmental ‘lapse rate’. Ice melt under thick debris was relatively insensitive to air temperature, while the effects of different temperature extrapolation methods were strongest at high elevation sites of thin and patchy debris cover.
format Article in Journal/Newspaper
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genre_facet Journal of Glaciology
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op_doi https://doi.org/10.1017/jog.2016.31
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Shaw, T.E., Brock, B.W., Fyffe, Catriona, Pellicciotti, F., Rutter, N. and Diotri, F. (2016) Air Temperature Distribution and Energy-balance Modelling of a Debris-covered Glacier. Journal of Glaciology, 62 (231). pp. 185-198. ISSN Print 0022-1430 Online 1727-5652
doi:10.1017/jog.2016.31
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publisher Cambridge University Press
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spelling ftunivworcester:oai:wrap.eprints.org:4761 2025-01-16T22:47:07+00:00 Air Temperature Distribution and Energy-balance Modelling of a Debris-covered Glacier Shaw, T.E. Brock, B.W. Fyffe, Catriona Pellicciotti, F. Rutter, N. Diotri, F. 2016-03-11 text http://eprints.worc.ac.uk/4761/ https://eprints.worc.ac.uk/4761/1/Shaw%20et%20al.,%202016.pdf https://doi.org/10.1017/jog.2016.31 en eng Cambridge University Press https://eprints.worc.ac.uk/4761/1/Shaw%20et%20al.,%202016.pdf Shaw, T.E., Brock, B.W., Fyffe, Catriona, Pellicciotti, F., Rutter, N. and Diotri, F. (2016) Air Temperature Distribution and Energy-balance Modelling of a Debris-covered Glacier. Journal of Glaciology, 62 (231). pp. 185-198. ISSN Print 0022-1430 Online 1727-5652 doi:10.1017/jog.2016.31 cc_by CC-BY GB Physical geography Article PeerReviewed 2016 ftunivworcester https://doi.org/10.1017/jog.2016.31 2022-03-02T19:58:55Z Near-surface air temperature is an important determinant of the surface energy balance of glaciers and is often represented by a constant linear temperature gradients (TGs) in models. Spatiotemporal variability in 2 m air temperature was measured across the debris-covered Miage Glacier, Italy, over an 89 d period during the 2014 ablation season using a network of 19 stations. Air temperature was found to be strongly dependent upon elevation for most stations, even under varying meteorological conditions and at different times of day, and its spatial variability was well explained by a locally derived mean linear TG (MG–TG) of −0.0088°C m−1. However, local temperature depressions occurred over areas of very thin or patchy debris cover. The MG–TG, together with other air TGs, extrapolated from both on- and off-glacier sites, were applied in a distributed energy-balance model. Compared with piecewise air temperature extrapolation from all on-glacier stations, modelled ablation, using the MG–TG, increased by <1%, increasing to >4% using the environmental ‘lapse rate’. Ice melt under thick debris was relatively insensitive to air temperature, while the effects of different temperature extrapolation methods were strongest at high elevation sites of thin and patchy debris cover. Article in Journal/Newspaper Journal of Glaciology University of Worcester: Worcester Research and Publications Journal of Glaciology 62 231 185 198
spellingShingle GB Physical geography
Shaw, T.E.
Brock, B.W.
Fyffe, Catriona
Pellicciotti, F.
Rutter, N.
Diotri, F.
Air Temperature Distribution and Energy-balance Modelling of a Debris-covered Glacier
title Air Temperature Distribution and Energy-balance Modelling of a Debris-covered Glacier
title_full Air Temperature Distribution and Energy-balance Modelling of a Debris-covered Glacier
title_fullStr Air Temperature Distribution and Energy-balance Modelling of a Debris-covered Glacier
title_full_unstemmed Air Temperature Distribution and Energy-balance Modelling of a Debris-covered Glacier
title_short Air Temperature Distribution and Energy-balance Modelling of a Debris-covered Glacier
title_sort air temperature distribution and energy-balance modelling of a debris-covered glacier
topic GB Physical geography
topic_facet GB Physical geography
url http://eprints.worc.ac.uk/4761/
https://eprints.worc.ac.uk/4761/1/Shaw%20et%20al.,%202016.pdf
https://doi.org/10.1017/jog.2016.31

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