Glacier crevasses: Observations, models, and mass balance implications

Colgan, William; Rajaram, Harihar; Abdalati, W.; McCutchan, Cheryl; Mottram, Ruth; Moussavi, M. S.; Grigsby, S.

doi:10.1002/2015rg000504

Cited by 172 publications

(226 citation statements)

References 272 publications

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“…Crevasse fields are mainly in response to the average bulk stress field, and when travelling through different stress regimes they can become rotated, or close to form crevasse traces. In addition, local discontinuities can also result in specific stress patterns and resulting local crevasses (Meier and others, 1974;Glasser and others, 1998;Hambrey and Lawson, 2000;Colgan and others, 2016). On Shackleton Glacier, expected crevasse patterns included: (i) arcuate upward and transverse crevasses in longitudinal extensional zones that correspond to increases in flow speed upstream of icefalls and in the narrowing trunk valley; (ii) longitudinal crevasses and active splaying crevasses indicating lateral extension at the base of the upper icefalls; (iii) marginal short splaying crevasses with angles of 45°in uniform velocity regions of the main trunk; (iv) upward splaying longer crevasses where the trunk enters the narrowing valley and marginal shear becomes high and compressive; and (v) some chevron and en echelon crevasses in rotating marginal bends in the upper and middle regions of the main trunk.…”

Section: Ice Flux Of Trunk Relative To Tributarymentioning

confidence: 99%

“…This results in a relatively deep trunk valley as evidenced by the steep exposed valley walls. Tributary centreline depths are based on visual interpretation of the broad shallow icefall with séracs, in combination with maximum crevasse depths from the creep relation and measurements in temperate glaciers, and from the stability of a free standing ice cliff (Cuffey and Paterson, 2010;Colgan and others, 2016). See Section 3.1.4 for verification of all chosen scenarios.…”

Section: Trunk and Tributary Ice Fluxmentioning

confidence: 99%

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Flow and structure in a dendritic glacier with bedrock steps

2017

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ABSTRACT. We analyse ice flow and structural glaciology of Shackleton Glacier, a dendritic glacier with multiple icefalls in the Canadian Rockies. A major tributary-trunk junction allows us to investigate the potential of tributaries to alter trunk flow and structure, and the formation of bedrock steps at confluences. Multi-year velocity-stake data and structural glaciology up-glacier from the junction were assimilated with glacier-wide velocity derived from Radarsat-2 speckle tracking. Maximum flow speeds are 65 m a −1 in the trunk and 175 m a −1 in icefalls. Field and remote-sensing velocities are in good agreement, except where velocity gradients are high. Although compression occurs in the trunk up-glacier of the tributary entrance, glacier flux is steady state because flow speed increases at the junction due to the funnelling of trunk ice towards an icefall related to a bedrock step. Drawing on a published erosion model, we relate the heights of the step and the hanging valley to the relative fluxes of the tributary and trunk. It is the first time that an extant glacier is used to test and support such model. Our study elucidates the inherent complexity of tributary/trunk interactions and provides a conceptual model for trunk flow restriction by a tributary in surge-type glaciers.

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Section: Ice Flux Of Trunk Relative To Tributarymentioning

confidence: 99%

Section: Trunk and Tributary Ice Fluxmentioning

confidence: 99%

Flow and structure in a dendritic glacier with bedrock steps

2017

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“…Colgan et al (2016) present an extensive review of the formation of crevasses, including basal crevasses and hydrofracturing. Observations of calving at Helheim Glacier using stereo photogrammetry suggest that a basal crevasse may be a key ingredient in establishing the onset and location of calving (James et al, 2014).…”

Section: Existing Calving Parameterizationsmentioning

confidence: 99%

An Intensive Observation of Calving at Helheim Glacier, East Greenland

et al. 2016

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“…Crevassing is another key process to lowering the viscosity of the ice through the delivery of meltwater to the bed and the fracturing/damage of the ice (e.g. Borstad and others, 2012;Colgan and others, 2015;Lüthi and others, 2015). Meltwater has easy access to the lower part of the ice column through crevasses, where it can lower the viscosity through cryohydrologic warming and hydraulic weakening of the ice, as the meltwater 564 Solgaard and others: Engabreen refreezes and latent heat is released.…”

Section: Discussionmentioning

confidence: 99%

Basal conditions at Engabreen, Norway, inferred from surface measurements and inverse modelling

et al. 2018

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ABSTRACT. Engabreen is an outlet glacier of the Svartisen Ice Cap located in Northern Norway. It is a unique glacier due to the Svartisen Subglacial Laboratory which allows direct access to the glacier bed. In this study, we combine both sub-and supraglacial observations with ice-flow modelling in order to investigate conditions at the bed of Engabreen both spatially and temporally. We use the full-Stokes model Elmer/Ice and satellite-based surface-velocity maps from 2010 and 2014 to infer patterns of basal friction. Direct measurements of basal sliding and deformation of lower layers of the ice are used to adjust the ice viscosity and provide essential input to the setup of our model and influence the interpretation of the results. We find a clear seasonal cycle in the subglacial conditions at the higher elevation region of the study area and discuss this in relation to the subglacial hydrological system. Our results also reveal an area with an overdeepening where basal friction is significantly lower than elsewhere on the glacier all year round. We attribute this to either water pooling at the base, or saturated sediments and increased strain heating at this location which softens the ice further.

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Glacier crevasses: Observations, models, and mass balance implications

Cited by 172 publications

References 272 publications

Flow and structure in a dendritic glacier with bedrock steps

Flow and structure in a dendritic glacier with bedrock steps

An Intensive Observation of Calving at Helheim Glacier, East Greenland

Basal conditions at Engabreen, Norway, inferred from surface measurements and inverse modelling

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