Borehole‐Based Characterization of Deep Mixed‐Mode Crevasses at a Greenlandic Outlet Glacier

Hubbard, Bryn; Christoffersen, Poul; Doyle, Samuel; Chudley, Thomas R.; Schoonman, Charlotte; Law, Robert; Bougamont, Marion

doi:10.1029/2020av000291

Cited by 18 publications

(27 citation statements)

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“…It is also possible to investigate the internal structure of valley glaciers, ice sheets, and ice shelves, by using a hot-water drill to create a borehole, which is then imaged and logged using an optical televiewer (e.g., Ashmore et al, 2017;Hubbard & Malone, 2013;Hubbard et al, 2008Hubbard et al, , 2021Roberson & Hubbard, 2010). The scanned image of the borehole is transformed to appear as a core; in this way structures such as primary stratification, crevasse traces, folds, and foliations can be measured.…”

Section: Structural Glaciological Analytical Methodsmentioning

confidence: 99%

“…However, this mechanism does not explain the apparently great depths to which crevasse traces penetrate. Borehole logging by optical televiewer of a crevassed zone of Store Glacier, a fast-flowing outlet glacier draining the Greenland Ice Sheet, revealed the presence of crevasse traces to a depth of 265 m (Hubbard et al, 2021). Furthermore, surface fracturing was inferred to extend to c. 400 m below the surface of the glacier, as indicated by excess ice temperatures.…”

Section: Crevasse Tracesmentioning

confidence: 99%

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Structures and Deformation in Glaciers and Ice Sheets

Jennings

Hambrey

2021

Reviews of Geophysics

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The purpose of this review is to provide a comprehensive assessment of the state of knowledge concerning the manner in which macroscopic structures evolve within glaciers, and to evaluate their meaning in terms of understanding the flow of glaciers and ice sheets. Using concepts drawn from structural geology (e.g., Fossen, 2010;Hobbs et al., 1976;Ramsay, 1967;Ramsay & Huber, 1983), attention is drawn to the similarities between glacier ice and deformed rocks. The review emphasizes those structures that can be observed at the glacier surface and considers their three-dimensional (3-D) geometry. Structures in glaciers are commonly complex and challenging to interpret, especially where several phases of deformation over-print one another. Hence, to aid the reader in the field, many of the described structures and their cross-cutting relationships are illustrated in photographs, maps, and conceptual diagrams, with examples ranging from the Arctic, through mid-latitude mountain ranges, to the Antarctic.

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Section: Structural Glaciological Analytical Methodsmentioning

confidence: 99%

Section: Crevasse Tracesmentioning

confidence: 99%

Structures and Deformation in Glaciers and Ice Sheets

Jennings

Hambrey

2021

Reviews of Geophysics

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“…However, the net effect of this on ice dynamics has yet to be identified. Additionally, crevasses that remain ponded and then refreeze at the end of the season will release latent heat and facilitate ice warming (Lüthi et al, 2015) at depths of up to hundreds of meters (Hubbard et al, 2021).…”

Section: Rapid Drainage Of Ponded Crevassesmentioning

confidence: 99%

“…Indeed, the use of simple stress thresholds to predict hydrological behavior is common across studies of GrIS supraglacial hydrology (Clason et al, 2015;Everett et al, 2016;Koziol et al, 2017;Poinar et al, 2015;Williamson, Banwell, et al, 2018;Williamson, Willis, et al, 2018). However, these thresholds are identified from observational studies performed with the aim of identifying suitable predictors of crevasse presence, not of crevasse hydrology (Hambrey & Müller, 1978;Harper et al, 1998;van der Veen, 1998;Vaughan, 1993); they may not even be suitable for that purpose (Mottram & Benn, 2009), as ice fracture is increasingly understood to be complex and multi-dimensional (Colgan et al, 2016;Hubbard et al, 2021;van der Veen, 1999). To date, no observational studies exist to support the use of any such controls, stress or otherwise, on the hydrological behavior of crevasses.…”

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confidence: 99%

Controls on Water Storage and Drainage in Crevasses on the Greenland Ice Sheet

et al. 2021

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Surface crevasses are open fractures in glaciers and ice sheets ranging in width from millimeters to tens of meters and in length from tens of meters to kilometers. Crevasses are a visible expression of a glacier's surface stress regimes; the size and orientation of crevasses are intrinsic to glacier dynamics as they are formed by extensional flow and deformation of ice through compression or shear (Colgan et al., 2016). Studying crevasses provides insight into glacier flow (Dell et al., 2019;Phillips et al., 2013) and it is important for the development of fracturing criteria for supraglacial lake drainage (

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Section: Introductionmentioning

confidence: 99%

Controls on water storage and drainage in crevasses on the Greenland Ice Sheet

Chudley

Christoffersen

Doyle³

et al. 2021

Preprint

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Surface crevasses on the Greenland Ice Sheet (GrIS) transfer nearly half of all the ice sheet's meltwater to the bed, yet when, where, and how this occurs is poorly understood. We use large-scale satellite analysis and uncrewed aerial vehicle (UAV) surveys to assess the spatial variability of meltwater ponding in crevasses across a fast-flowing sector of the western GrIS. Between 2017 and 2019 an average of a quarter of crevasse fields ponded, in roughly the same area every year. However, the locations of such ponding cannot be explained in the same way as supraglacial lakes, which collect in surface basins. Instead, we find that ponded crevasses exist in regions of compressive surface stress. We suggest that this is because compressive regimes close pathways that elsewhere allow crevasses to drain into the wider surface hydrological system. Using UAV surveys, we show that these ponded crevasses instead drain rapidly to the bed by hydrofracture. Differing drainage processes in regions of compressive and extensional regimes may have distinct consequences for subglacial drainage and the heating of the ice sheet due to energy release during meltwater refreezing.

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Borehole‐Based Characterization of Deep Mixed‐Mode Crevasses at a Greenlandic Outlet Glacier

Cited by 18 publications

References 50 publications

Structures and Deformation in Glaciers and Ice Sheets

Structures and Deformation in Glaciers and Ice Sheets

Controls on Water Storage and Drainage in Crevasses on the Greenland Ice Sheet

Controls on water storage and drainage in crevasses on the Greenland Ice Sheet

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