Ice viscosity governs hydraulic fracture causing rapid drainage of supraglacial lakes

Full thickness crevasses can transport water from the glacier surface to the bedrock where high water pressures can open kilometre-long cracks along the basal interface, which can accelerate glacier flow. We present a first computational modelling study that describes time-dependent fracture propaga...

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Bibliographic Details
Main Authors: Hageman, Tim, Mejía, Jessica, Duddu, Ravindra, Martínez-Pañeda, Emilio
Format: Text
Language:English
Published: 2024
Subjects:
Greenland
Rapid Lake
glacier
Ice Sheet
Online Access:https://doi.org/10.5194/egusphere-2024-346
https://egusphere.copernicus.org/preprints/2024/egusphere-2024-346/
Description
Summary:Full thickness crevasses can transport water from the glacier surface to the bedrock where high water pressures can open kilometre-long cracks along the basal interface, which can accelerate glacier flow. We present a first computational modelling study that describes time-dependent fracture propagation in an idealised glacier causing rapid supraglacial lake drainage. A novel two-scale numerical method is developed to capture the elastic and viscoplastic deformations of ice along with crevasse propagation. The fluid-conserving thermo-hydro-mechanical model incorporates turbulent fluid flow and accounts for melting/refreezing in fractures. Applying this model to observational data from a 2008 rapid lake drainage event indicates that viscous deformation exerts a much stronger control on hydrofracture propagation compared to thermal effects. This finding contradicts the conventional assumption that elastic deformation is adequate to describe fracture propagation in glaciers over short timescales (minutes to several hours) and instead demonstrates that viscous deformation must be considered to reproduce observations of lake drainage rate and local ice surface elevation change. As supraglacial lakes continue expanding inland and as Greenland Ice Sheet temperatures become warmer than -8 °C, our results suggest rapid lake drainages are likely to occur without refreezing, which has implications for the rate of sea level rise.

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