New insights into ice accumulation at Galena Creek Rock Glacier from radar imaging of its internal structure

The ice-cored Galena Creek Rock Glacier, Wyoming, USA, has been the subject of a number of studies that sought to determine the origin of its ice. We present new observations of the rock glacier's internal structure from ground-penetrating radar to constrain ice and debris distribution and accu...

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Published inJournal of glaciology Vol. 66; no. 255; pp. 1 - 10
Main Authors Petersen, Eric Ivan, Levy, Joseph S., Holt, John W., Stuurman, Cassie M.
Format Journal Article
LanguageEnglish
Published Cambridge Cambridge University Press 01.02.2020
Subjects
Accumulation
Avalanches
Chutes
Coastal inlets
Creeks
Debris
debris-covered glaciers
Detritus
Dipping
Distribution
Glacial drift
glacier geophysics
Glaciers
Ground penetrating radar
Ice
Ice accumulation
Imaging techniques
Radar
Radar imaging
Reflectors
Rock glaciers
Rocks
Snow
Snow accumulation
Snowfall
Snowpack
supraglacial debris
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Summary:The ice-cored Galena Creek Rock Glacier, Wyoming, USA, has been the subject of a number of studies that sought to determine the origin of its ice. We present new observations of the rock glacier's internal structure from ground-penetrating radar to constrain ice and debris distribution and accumulation. We imaged dipping reflectors in the center of the glacier that are weak and discontinuous, in contrast to strong reflectors toward the edge of the cirque beneath large debris-avalanche chutes. These reflectors form a network of concave-up, up-glacier dipping layers. We interpret these as englacial debris bands formed by large debris falls buried by subsequent ice and snow accumulation. They are discontinuous where ice outpaces debris accumulation, but with sufficient debris accumulation an interleaved pattern of ice and debris layers can form. We propose a model in which the ice in these interleaved layers is snowfall preserved by debris-facilitated accumulation. Large debris falls that occur in early spring bury sections of the snowpack, which are then preserved through summer and incorporated into the rock glacier body over time. This study highlights the importance of sequential accumulation of ice and debris for understanding the dynamics of rock glaciers and debris-covered glaciers.
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ISSN:0022-1430
1727-5652
DOI:10.1017/jog.2019.67