Modelling spatial patterns of near-surface air temperature over a decade of melt seasons on McCall Glacier, Alaska

Abstract We examine the spatial patterns of near-surface air temperature ( T a ) over a melting glacier using a multi-annual dataset from McCall Glacier, Alaska. The dataset consists of a 10-year (2005–2014) meteorological record along the glacier centreline up to an upper glacier cirque, spanning a...

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Bibliographic Details
Published in:Journal of Glaciology
Main Authors: Troxler, Patrick, Ayala, Álvaro, Shaw, Thomas E., Nolan, Matt, Brock, Ben W., Pellicciotti, Francesca
Format: Article in Journal/Newspaper
Language:English
Published: Cambridge University Press (CUP) 2020
Subjects:
McCall
glacier
Journal of Glaciology
Alaska
Online Access:http://dx.doi.org/10.1017/jog.2020.12
https://www.cambridge.org/core/services/aop-cambridge-core/content/view/S002214302000012X
Description
Summary:Abstract We examine the spatial patterns of near-surface air temperature ( T a ) over a melting glacier using a multi-annual dataset from McCall Glacier, Alaska. The dataset consists of a 10-year (2005–2014) meteorological record along the glacier centreline up to an upper glacier cirque, spanning an elevation difference of 900 m. We test the validity of on-glacier linear lapse rates, and a model that calculates T a based on the influence of katabatic winds and other heat sources along the glacier flow line. During the coldest hours of each summer (10% of time), average lapse rates across the entire glacier range from −4.7 to −6.7°C km −1 , with a strong relationship between T a and elevation ( R 2 > 0.7). During warm conditions, T a shows more complex, non-linear patterns that are better explained by the flow line-dependent model, reducing errors by up to 0.5°C compared with linear lapse rates, although more uncertainty might be associated with these observations due to occasionally poor sensor ventilation. We conclude that T a spatial distribution can vary significantly from year to year, and from one glacier section to another. Importantly, extrapolations using linear lapse rates from the ablation zone might lead to large underestimations of T a on the upper glacier areas.

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