Terminus change of Kaskawulsh Glacier, Yukon, under a warming climate: retreat, thinning, slowdown and modified proglacial lake geometry

Author:

Main BrittanyORCID,Copland LukeORCID,Smeda BradenORCID,Kochtitzky WillORCID,Samsonov SergeyORCID,Dudley JonathanORCID,Skidmore MarkORCID,Dow ChristineORCID,Van Wychen Wesley,Medrzycka DorotaORCID,Higgs EricORCID,Mingo LaurentORCID

Abstract

Abstract Links between proglacial lakes and glacier dynamics are poorly understood but are necessary to predict how mountain glaciers will react to a warmer, wetter climate, where such lakes are expected to increase both in number and volume. Here, we examine a long-term (~120 year) record of terminus retreat, thinning and surface velocities from in-situ and remote sensing observations at the terminus of Kaskawulsh Glacier, Yukon, Canada, and determine the impact of a local proglacial hydrological reorganisation on glacier dynamics. After an initial deceleration during the late 1990s, terminus velocities increased at a rate of 3 m a−2 from 2000–12, while proglacial Slims Lake area increased simultaneously. The rapid drainage of the lake in May 2016 substantially altered the velocity profile, decreasing annual velocities by 48% within 3 km of the terminus between 2015 and 2021, at an average rate of ~ 12.5 m a−2. A key cause of the rapid drop in glacier motion was a reduction in flotation of the lower part of the glacier terminus after lake drainage. This has important implications for glacier dynamics and provides one of the first assessments of the impacts of a rapid proglacial lake drainage event on local terminus velocities.

Publisher

Cambridge University Press (CUP)

Subject

Earth-Surface Processes

Reference64 articles.

1. Continuity of the Mass Loss of the World's Glaciers and Ice Caps From the GRACE and GRACE Follow‐On Missions

2. Derivation and analysis of a complete modern-date glacier inventory for Alaska and northwest Canada

3. Timing and potential causes of 19th-century advances in coastal Alaska based on tree-ring dating and historical accounts;Gaglioti;Frontiers in Earth Sciences,2019

4. Density of Glacier Ice

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