Differential impact of isolated topographic bumps on ice sheet flow and subglacial processes

IF 4.4 2区地球科学 Q1 GEOGRAPHY, PHYSICAL

Cryosphere Pub Date : 2023-06-22 DOI:10.5194/tc-17-2477-2023

M. McKenzie, Lauren E. Miller, Jacob S. Slawson, E. Mackie, Shujie Wang

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引用次数: 0

Abstract

Abstract. Topographic highs (“bumps”) across glaciated landscapes have the potential to temporarily slow ice sheet flow or, conversely, accelerate ice flow through subglacial strain heating and meltwater production. Isolated bumps of variable size across the deglaciated landscape of the Cordilleran Ice Sheet (CIS) of Washington State present an opportunity to study the influence of topographic highs on ice–bed interactions and ice flow organization. This work utilizes semi-automatic mapping techniques of subglacial bedforms to characterize the morphology of streamlined subglacial bedforms including elongation, surface relief, and orientation, all of which provide insight into subglacial processes during post-Last Glacial Maximum deglaciation. We identify a bump-size threshold of several cubic kilometers – around 4.5 km3 – in which bumps larger than this size will consistently and significantly disrupt both ice flow organization and subglacial sedimentary processes, which are fundamental to the genesis of streamlined subglacial bedforms. Additionally, sedimentary processes are persistent and well developed downstream of bumps, as reflected by enhanced bedform elongation and reduced surface relief, likely due to increased availability and production of subglacial sediment and meltwater. While isolated topography plays a role in disrupting ice flow, larger bumps have a greater disruption to ice flow organization, while bumps below the identified threshold seem to have little effect on ice and subglacial processes. The variable influence of isolated topographic bumps on ice flow of the CIS has significant implications for outlet glaciers of the Greenland Ice Sheet (GrIS) due to similarities in regional topography, where local bumps are largely unresolved.

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孤立的地形起伏对冰盖流动和冰下过程的差异影响

摘要冰川景观上的地形高点（“凸起”）有可能暂时减缓冰盖的流动，或者相反，通过冰下应变加热和融水的产生加速冰的流动。华盛顿州科迪勒兰冰原（CIS）冰川消融景观中大小不等的孤立凸起为研究地形高点对冰床相互作用和冰流组织的影响提供了机会。这项工作利用半自动绘制冰下底型的技术来表征流线型冰下底形的形态，包括延伸、表面起伏和方向，所有这些都为了解末次冰川最大值消退后的冰下过程提供了见解。我们确定了一个数立方公里的凸起大小阈值，大约为4.5 km3–其中大于该尺寸的凸起将持续且显著地破坏冰流组织和冰下沉积过程，而冰流和冰下沉积物过程是层状冰下床型形成的基础。此外，沉积过程是持久的，在凸起的下游发育良好，表现为形态延伸的增强和表面起伏的减少，这可能是由于冰下沉积物和融水的可利用性和产量的增加。尽管孤立地形在破坏冰流方面发挥了作用，但较大的隆起对冰流组织的破坏更大，而低于确定阈值的隆起似乎对冰和冰下过程影响不大。由于区域地形的相似性，独联体孤立地形隆起对冰流的可变影响对格陵兰冰盖（GrIS）的出口冰川具有重要意义，而区域地形隆起在很大程度上没有得到解决。

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

Cryosphere GEOGRAPHY, PHYSICAL-GEOSCIENCES, MULTIDISCIPLINARY

CiteScore

8.70

自引率

17.30%

发文量

240

审稿时长

4-8 weeks

期刊介绍： The Cryosphere (TC) is a not-for-profit international scientific journal dedicated to the publication and discussion of research articles, short communications, and review papers on all aspects of frozen water and ground on Earth and on other planetary bodies. The main subject areas are the following: ice sheets and glaciers; planetary ice bodies; permafrost and seasonally frozen ground; seasonal snow cover; sea ice; river and lake ice; remote sensing, numerical modelling, in situ and laboratory studies of the above and including studies of the interaction of the cryosphere with the rest of the climate system.