Sea Ice Mechanics Research Progress.

The architecture for a new large scale (5 to 100 km, 1 hour to 1 day) sea ice dynamics model based on an anisotropic constitutive law is presented here. This architecture accounts directly for refrozen lead systems in the pack ice strength (with an anisotropic failure surface) and in the ice thickne...

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Bibliographic Details
Main Author: Coon, Max D.
Other Authors: NORTHWEST RESEARCH ASSOCIATES INC BELLEVUE WA
Format: Text
Language:English
Published: 1997
Subjects:
Snow
Ice and Permafrost
*ICE MECHANICS
*SEA ICE
SCALE MODELS
DEFORMATION
FRACTURE(MECHANICS)
ANISOTROPY
SHEAR STRESSES
ELASTOPLASTICITY
BUOYS
ICE DYNAMICS MODELS
Ice
permafrost
Sea ice
Online Access:http://www.dtic.mil/docs/citations/ADA327636
http://oai.dtic.mil/oai/oai?&verb=getRecord&metadataPrefix=html&identifier=ADA327636
Description
Summary:The architecture for a new large scale (5 to 100 km, 1 hour to 1 day) sea ice dynamics model based on an anisotropic constitutive law is presented here. This architecture accounts directly for refrozen lead systems in the pack ice strength (with an anisotropic failure surface) and in the ice thickness distribution (with an oriented thickness distribution). The lower limit (5 km) of the model resolution is controlled by the fracture spacing of old, thicker ice and the maximum lead width. The upper limit of the model resolution (100 km) is controlled by curvature in the lead directions and variations in the lead width. These in turn are controlled by the variations in internal ice stress due to driving forces (winds and currents), which set the time resolution. This architecture features abrupt changes in the failure surface and the associated flow rule that cannot be averaged over a time step. In addition, the principal stress normal to a new lead must be zero as it opens. This model has sub-scale simulations that allow for the inclusion of phenomena such as ridging, rafting, buckling, and fracture on the behavior of the ice. With this new ice constitutive law, it is possible to directly test the ice failure strength, plastic flow rule, and ice thickness distribution. The data most useful for this testing come from ice stress and position buoys together with SAR deformation data. Some data comparisons have already been made.

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