On nonlinear strain theory for a viscoelastic material model and its implications for calving of ice shelves

In the current ice-sheet models calving of ice shelves is based on phenomenological approaches. To obtain physics-based calving criteria, a viscoelastic Maxwell model is required accounting for short-term elastic and long-term viscous deformation. On timescales of months to years between calving eve...

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Bibliographic Details
Published in:Journal of Glaciology
Main Authors: JULIA CHRISTMANN, RALF MÜLLER, ANGELIKA HUMBERT
Format: Article in Journal/Newspaper
Language:English
Published: Cambridge University Press 2019
Subjects:
calving
ice-sheet modeling
ice shelves
Environmental sciences
GE1-350
Meteorology. Climatology
QC851-999
Ice Sheet
Ice Shelf
Ice Shelves
Journal of Glaciology
Online Access:https://doi.org/10.1017/jog.2018.107
https://doaj.org/article/50c07ae8c0404b5995880017c949d259
Description
Summary:In the current ice-sheet models calving of ice shelves is based on phenomenological approaches. To obtain physics-based calving criteria, a viscoelastic Maxwell model is required accounting for short-term elastic and long-term viscous deformation. On timescales of months to years between calving events, as well as on long timescales with several subsequent iceberg break-offs, deformations are no longer small and linearized strain measures cannot be used. We present a finite deformation framework of viscoelasticity and extend this model by a nonlinear Glen-type viscosity. A finite element implementation is used to compute stress and strain states in the vicinity of the ice-shelf calving front. Stress and strain maxima of small (linearized strain measure) and finite strain formulations differ by ~ 5% after 1 and by ~ 30% after 10 years, respectively. A finite deformation formulation reaches a critical stress or strain faster, thus calving rates will be higher, despite the fact that the exact critical values are not known. Nonlinear viscosity of Glen-type leads to higher stress values. The Maxwell material model formulation for finite deformations presented here can also be applied to other glaciological problems, for example, tidal forcing at grounding lines or closure of englacial and subglacial melt channels.

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