Failure strength of glacier ice inferred from Greenland crevasses

Ice fractures when subject to stress that exceeds the material failure strength. Previous studies have found that a von Mises failure criterion, which places a bound on the second invariant of the deviatoric stress tensor, is consistent with empirical data. Other studies have suggested that a scalin...

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Bibliographic Details
Published inThe cryosphere Vol. 18; no. 4; pp. 1947 - 1957
Main Authors Grinsted, Aslak, Rathmann, Nicholas Mossor, Mottram, Ruth, Solgaard, Anne Munck, Mathiesen, Joachim, Hvidberg, Christine Schøtt
Format Journal Article
LanguageEnglish
Published Katlenburg-Lindau Copernicus GmbH 26.04.2024
Copernicus Publications
Subjects
Analysis
Crevasses
Criteria
Datasets
Empirical analysis
Fractures
Glacier ice
Glaciers
Ice sheets
Large-scale models
Materials failure
Modelling
Remote sensing
Scaling
Shear strain
Strength
Surface velocity
Temperature
Tensile strength
Tensors
Velocity
Greenland
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Summary:Ice fractures when subject to stress that exceeds the material failure strength. Previous studies have found that a von Mises failure criterion, which places a bound on the second invariant of the deviatoric stress tensor, is consistent with empirical data. Other studies have suggested that a scaling effect exists, such that larger sample specimens have a substantially lower failure strength, implying that estimating material strength from laboratory-scale experiments may be insufficient for glacier-scale modeling. In this paper, we analyze the stress conditions in crevasse onset regions to better understand the failure criterion and strength relevant for large-scale modeling. The local deviatoric stress is inferred using surface velocities and reanalysis temperatures, and crevasse onset regions are extracted from a remotely sensed crevasse density map. We project the stress state onto the failure plane spanned by Haigh–Westergaard coordinates, showing how failure depends on mode of stress. We find that existing crevasse data are consistent with a Schmidt–Ishlinsky failure criterion that places a bound on the absolute value of the maximal principal deviatoric stress, estimated to be 158±44 kPa. Although the traditional von Mises failure criterion also provides an adequate fit to the data with a von Mises strength of 265±73 kPa, it depends only on stress magnitude and is indifferent to the specific stress state, unlike Schmidt–Ishlinsky failure which has a larger shear failure strength compared to tensile strength. Implications for large-scale ice flow and fracture modeling are discussed.
ISSN:1994-0424
1994-0416
1994-0424
1994-0416
DOI:10.5194/tc-18-1947-2024