Evolution of the dynamics of Airdrop Glacier, western Axel Heiberg Island, over a seven decade long advance

IF 2.7 3区地球科学 Q2 ECOLOGY

Arctic Science Pub Date : 2023-08-31 DOI:10.1139/as-2022-0045

Benoît Lauzon, L. Copland, W. Van Wychen, W. Kochtitzky, R. McNabb

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Abstract

Various remotely sensed data, including historical aerial photographs, declassified intelligence satellite photographs, optical satellite imagery, and synthetic aperture radar data were used to undertake the first comprehensive reconstruction of the dynamics of Airdrop Glacier on Axel Heiberg Island, Nunavut. Observations show a continuous terminus advance totalling ~6 km since 1950 and notably less variability in its surface velocities in comparison to adjacent Iceberg Glacier. This advance is concurrent with relatively high flow rates over its entire surface, resulting in significant thickening near the terminus, and thinning at higher elevations. Velocities have more than halved from the mid-2000s to 2021, but without any definitive evidence of previous flow instabilities, we cannot confirm whether Airdrop’s behaviour is cyclic in nature and therefore characteristic of a surge. Instead, Airdrop Glacier could be experiencing a delayed response to positive mass balance conditions of the Little Ice Age, which could also explain the advance of other nearby glaciers. Its recent slowdown could then be indicative of a gradual adjustment to recent climatic conditions. This study highlights the need for comprehensive studies of glacier dynamics in the Canadian Arctic to improve our understanding of the factors triggering dynamic instabilities and causing the observed variety of behaviours.

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阿克塞尔海伯格岛西部空投冰川的动态演变，历时70年

利用各种遥感数据，包括历史航空照片、解密情报卫星照片、光学卫星图像和合成孔径雷达数据，对Nunavut Axel Heiberg岛空投冰川的动态进行了首次综合重建。观测显示，自1950年以来，终末冰川连续前进了约6公里，与邻近的冰山冰川相比，其表面速度的变异性明显较小。这种进步与整个表面的相对高流速同时发生，导致在末端附近显着增厚，在较高海拔处变薄。从2000年代中期到2021年，速度下降了一半以上，但由于没有任何明确的证据表明之前的流动不稳定，我们无法确认Airdrop的行为是否具有周期性，因此是否是激增的特征。相反，空投冰川可能正在经历对小冰期正质量平衡条件的延迟反应，这也可以解释附近其他冰川的前进。因此，最近的放缓可能预示着对近期气候条件的逐渐调整。这项研究强调了对加拿大北极地区冰川动力学进行全面研究的必要性，以提高我们对触发动态不稳定性和导致观察到的各种行为的因素的理解。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Arctic Science Agricultural and Biological Sciences-General Agricultural and Biological Sciences

CiteScore

5.00

自引率

12.10%

发文量

期刊介绍： Arctic Science is an interdisciplinary journal that publishes original peer-reviewed research from all areas of natural science and applied science & engineering related to northern Polar Regions. The focus on basic and applied science includes the traditional knowledge and observations of the indigenous peoples of the region as well as cutting-edge developments in biological, chemical, physical and engineering science in all northern environments. Reports on interdisciplinary research are encouraged. Special issues and sections dealing with important issues in northern polar science are also considered.