What can radar-based measures of subglacial hydrology tell us about basal shear stress? A case study at Thwaites Glacier, West Antarctica

IF 2.8 3区地球科学 Q2 GEOGRAPHY, PHYSICAL

Journal of Glaciology Pub Date : 2024-01-15 DOI:10.1017/jog.2024.3

Rohaiz Haris, Winnie Chu, Alexander Robel

引用次数: 0

Abstract

: Ice sheet models use observations to infer basal shear stress, but the variety of methods and datasets available has resulted in a wide range of estimates. Radar-based metrics such as reflectivity and specularity have been used to characterize subglacial hydrologic conditions that are linked to spatial variations in basal shear stress. We explore whether radar metrics can be used to inform models about basal shear stress. At Thwaites Glacier, West Antarctica, we sample basal shear stress inversions across a wide range of ice sheet models to see how the basal shear stress distribution changes in regions of varying reflectivity and specularity. Our results reveal three key findings: (1) Regions of high specularity exhibit lower mean basal shear stresses (2) Wet and bumpy regions, as characterized by high reflectivity and low specularity, exhibit higher mean basal shear stresses (3) Models disagree about what basal shear stress should be at the onset of rapid ice flow and high basal melt where reflectivity is low.

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基于雷达的冰川下水文测量能告诉我们什么是基底剪应力？南极洲西部 Thwaites 冰川案例研究

:冰盖模型利用观测数据来推断基底切应力，但由于方法和数据集的多样性，导致估算结果差异很大。雷达指标（如反射率和镜面反射率）被用来描述冰川下的水文条件，这些条件与基底切应力的空间变化有关。我们探讨了雷达指标是否可用于为基底剪应力模型提供信息。在南极洲西部的 Thwaites 冰川，我们对各种冰盖模型的基底切应力反演进行了采样，以了解基底切应力分布在不同反射率和镜面反射区域的变化情况。我们的研究结果揭示了三个重要发现：（1）镜面反射率高的区域表现出较低的平均基底剪切应力（2）以高反射率和低镜面反射率为特征的潮湿和凹凸不平区域表现出较高的平均基底剪切应力（3）在反射率较低的快速冰流和高基底融化开始时，模型对基底剪切应力应该是多少存在分歧。

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

Journal of Glaciology 地学-地球科学综合

CiteScore

5.80

自引率

14.70%

发文量

101

审稿时长

6 months

期刊介绍： Journal of Glaciology publishes original scientific articles and letters in any aspect of glaciology- the study of ice. Studies of natural, artificial, and extraterrestrial ice and snow, as well as interactions between ice, snow and the atmospheric, oceanic and subglacial environment are all eligible. They may be based on field work, remote sensing, laboratory investigations, theoretical analysis or numerical modelling, or may report on newly developed glaciological instruments. Subjects covered recently in the Journal have included palaeoclimatology and the chemistry of the atmosphere as revealed in ice cores; theoretical and applied physics and chemistry of ice; the dynamics of glaciers and ice sheets, and changes in their extent and mass under climatic forcing; glacier energy balances at all scales; glacial landforms, and glaciers as geomorphic agents; snow science in all its aspects; ice as a host for surface and subglacial ecosystems; sea ice, icebergs and lake ice; and avalanche dynamics and other glacial hazards to human activity. Studies of permafrost and of ice in the Earth’s atmosphere are also within the domain of the Journal, as are interdisciplinary applications to engineering, biological, and social sciences, and studies in the history of glaciology.