Structural Evolution During Cyclic Glacier Surges: 1. Structural Glaciology of Trapridge Glacier, Yukon, Canada

Hambrey, Michael J.

doi:10.1029/2018jf004869

Cited by 10 publications

(47 citation statements)

References 81 publications

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“…We begin by developing a digital elevation model (DEM) of bed topography that corresponds to a simplified version of Trapridge Glacier which we refer to as “Traplike Glacier.” Traplike Glacier flows from west to east and is symmetric about its centerline flow axis. This symmetry is produced by taking the DEM for Trapridge Glacier bed topography B ( x , y ) (derived from Flowers & Clarke, , and extended using a simplified version of Clarke et al, ) and identifying the central flow axis for Trapridge Glacier (refer to Figure 11 of Hambrey & Clarke, ), rotating the DEM to align with this axis, resampling the DEM in the rotated grid, and then cropping the new DEM to isolate the Trapridge Glacier catchment. We denote the gridded bed elevation for the new DEM as B i , j , where i =1,2,…, N x and j =1,2,…, N y and assume that N y is an odd number so that j =1 + ( N y − 1)/2 corresponds to the j index of the glacier centerline.…”

Section: Structure Modelingmentioning

confidence: 99%

“…Large bedrock bumps complicate the flow of Trapridge Glacier (e.g., Hambrey & Clarke, , Figure 3). By avoiding the full complexity of Trapridge Glacier, we can systematically examine how subglacial topography influences ice flow and ice structure.…”

Section: Structure Modelingmentioning

confidence: 99%

“…The right channel surge model examines the case where the southern half of the glacier experiences cyclic changes in the basal sliding friction while the northern half has constant sliding friction throughout the surge cycle (Figure ). Hambrey and Clarke () suggest that the south channel (i.e., to the south of the medial moraine) shows clearer evidence for surging than the north channel. The simplified model allows the consequences of such a channelization to be explored.…”

Section: Structure Modelingmentioning

confidence: 99%

“…This contribution aims to provide a quantitative framework for interpreting a companion paper (Hambrey & Clarke, ) on the measured and modeled structure of Trapridge Glacier, Yukon, Canada (61°14 ′ N, 140°20 ′ W), a well‐studied glacier that from circa 1980–1999 experienced a slow surge (Frappé‐Sénéclauze & Clarke, ). Combining field observations and numerical modeling, Hambrey and Clarke () analyzed the postsurge structure of Trapridge Glacier including the medial moraine pattern, stratification and foliation, folding, and the density and orientation of crevasse traces. That paper was concerned with the observed structures and the skill of prognostic models to reproduce observations.…”

Section: Introductionmentioning

confidence: 99%

“…We follow the template of Table 1 in Hambrey and Clarke () and use standard structural geological notation to label glacier structures: S 0 , S 1 , and so forth, for sequential planar structures and F 1 , F 2 , and so forth, for successive fold phases. In the present paper we consider primary stratification (S 0 ), longitudinal foliation (S 1 ), transverse foliation (S 2 ), fractures (surface crevassing and crevasse traces; S 4 ), recumbent folds (F 3 ), and medial moraines.…”

Section: Introductionmentioning

confidence: 99%

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Structural Evolution During Cyclic Glacier Surges: 2. Numerical Modeling

Hambrey

2019

JGR Earth Surface

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The mesoscale structures of a glacier express the history of flow, temperature, and stress. Thus, in principle, numerical ice dynamics models have sufficient physics to examine the formation and transport of these structures. In this study we use a vertically integrated thermomechanical ice dynamics model to simulate the temporally evolving patterns of surficial moraine, stratification, foliation, and folding of glacier ice, and the density and orientation of traces of former crevasses. The modeled glaciers are simplified versions of Trapridge Glacier in northwest Canada that allow diagnostic modeling of influences on glacier structure and help to clarify the physics and numerics. In the model, surges occur every 50 years in response to a prescribed cyclic change in bed friction. Medial moraine patterns are simulated by tracking the englacial and supraglacial trajectory of debris injected at fixed points in the accumulation region. Stratification is assumed to be associated with isochronal surfaces, and vertical foliation is explained in terms of horizontal flattening of strain ellipsoids. Crevasses form when and where the intensity of tensile stress exceeds a prescribed threshold; crack damage is cumulative so that crevasse traces observed at sampling sites are a superposition of the damage accumulated en route. Folding is parameterized but not resolved. By evaluating the deformation gradient tensor along ice particle trajectories and applying the polar decomposition to this tensor, we isolate the cumulative effects of rotation and stretching by ice flow and calculate strain ellipsoids as well as other practical indicators of deformation.

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Section: Structure Modelingmentioning

confidence: 99%

Section: Structure Modelingmentioning

confidence: 99%

Section: Structure Modelingmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Structural Evolution During Cyclic Glacier Surges: 2. Numerical Modeling

Hambrey

2019

JGR Earth Surface

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Topographic controls on ice flow and recession for Juneau Icefield (Alaska/British Columbia)

Davies

Bendle

Carrivick

et al. 2022

Earth Surf Processes Landf

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Globally, mountain glaciers and ice caps are losing dramatic volumes of ice. The resultant sea‐level rise is dominated by contributions from Alaska. Plateau icefields may be especially sensitive to climate change due to the non‐linear controls their topography imparts on their response to climate change. However, Alaskan plateau icefields have been subject to little structural glaciological or regional geomorphological assessment, which makes the controls on their present and former mass balance difficult to ascertain. We inventoried 1050 glaciers and 368 lakes in the Juneau Icefield region for the year 2019. We found that 63 glaciers had disappeared since the 2005 inventory, with a reduction in glacier area of 422 km2 (10.0%). We also present the first structural glaciological and geomorphological map for an entire icefield in Alaska. Glaciological mapping of >20 800 features included crevasses, debris cover, foliation, ogives, medial moraines and, importantly, areas of glacier fragmentation, where glaciers either separated from tributaries via lateral recession (n = 59), or disconnected within areas of former icefalls (n = 281). Geomorphological mapping of >10 200 landforms included glacial moraines, glacial lakes, trimlines, flutes and cirques. These landforms were generated by a temperate icefield during the Little Ice Age (LIA) neoglaciation. These data demonstrate that the present‐day outlet glaciers, which have a similar thermal and ice‐flow regime, have undergone largely continuous recession since the LIA. Importantly, disconnections occurring within glaciers can separate accumulation and ablation zones, increasing rates of glacier mass loss. We show that glacier disconnections are widespread across the icefield and should be critically taken into consideration when icefield vulnerability to climate change is considered.

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Applications of semi-Lagrangian methods in the geosciences

Fletcher

2020

Semi-Lagrangian Advection Methods and Their Applications in Geoscience

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Structural Evolution During Cyclic Glacier Surges: 1. Structural Glaciology of Trapridge Glacier, Yukon, Canada

Cited by 10 publications

References 81 publications

Structural Evolution During Cyclic Glacier Surges: 2. Numerical Modeling

Structural Evolution During Cyclic Glacier Surges: 2. Numerical Modeling

Topographic controls on ice flow and recession for Juneau Icefield (Alaska/British Columbia)

Applications of semi-Lagrangian methods in the geosciences

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