The influence of firn layer material properties on surface crevasse propagation in glaciers and ice shelves

Linear elastic fracture mechanics (LEFM) models have been used to estimate crevasse depths in glaciers and to represent iceberg calving in ice sheet models. However, existing LEFM models assume glacier ice to be homogeneous and utilize the mechanical properties of fully consolidated ice. Using depth...

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Bibliographic Details
Published in:The cryosphere 2024-12, Vol.18 (12), p.5573-5593
Main Authors: Clayton, Theo, Duddu, Ravindra, Hageman, Tim, Martínez-Pañeda, Emilio
Format: Article
Language:English
Subjects:
Analysis
Boreholes
Boundary conditions
Crack propagation
Deformation
Density
Elastic properties
Environmental aspects
Environmental factors
Exact solutions
Firn
Firn density
Floating ice
Fracture mechanics
Geometry
Glaciation
Glacier ice
Glacier variations
Glaciers
Ice
Ice calving
Ice sheet models
Ice sheets
Ice shelves
Iceberg calving
Icebergs
Land ice
Linear elastic fracture mechanics
Material properties
Mechanical properties
Modulus of elasticity
Penetration depth
Propagation
Stress propagation
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Summary:Linear elastic fracture mechanics (LEFM) models have been used to estimate crevasse depths in glaciers and to represent iceberg calving in ice sheet models. However, existing LEFM models assume glacier ice to be homogeneous and utilize the mechanical properties of fully consolidated ice. Using depth-invariant properties is not realistic as the process of compaction from unconsolidated snow to firn to glacial ice is dependent on several environmental factors, typically leading to a lower density and Young's modulus in upper surface strata. New analytical solutions for longitudinal-stress profiles are derived using depth-varying properties based on borehole data from the Ronne Ice Shelf and are used in an LEFM model to determine the maximum penetration depths of an isolated crevasse in grounded glaciers and floating ice shelves. These maximum crevasse depths are compared to those obtained for homogeneous glacial ice, showing the importance of including the effect of the upper unconsolidated firn layers on crevasse propagation. The largest reductions in the penetration depth ratio were observed for shallow grounded glaciers, with variations in Young's modulus being more influential than firn density (maximum differences in crevasse depth of 46 % and 20 %, respectively), whereas firn density changes resulted in an increase in penetration depth for thinner floating ice shelves (95 %-188 % difference in crevasse depth between constant and depth-varying properties). Thus, our study shows that the firn layer can increase the vulnerability of ice shelves to fracture and calving, highlighting the importance of considering depth-dependent firn layer material properties in LEFM models for estimating crevasse penetration depths and predicting rift propagation.
ISSN:1994-0416
1994-0424
1994-0416
1994-0424
DOI:10.5194/tc-18-5573-2024