Stochastic Analysis of Satellite-derived Arctic Sea Ice Information and Acceleration Proposal to Support N00014-02-1-0244
Sea-ice motion falls under the larger category of non-rigid motion analysis [Kambhamettu et al., 1994 1998, 2002]. The interdisciplinary field of non-rigid motion involves the understanding of three basic types of materials, namely, continuous, piece-wise continuous, and discrete particle motion. De...
Main Authors: | , , , |
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Format: | Text |
Language: | English |
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2003
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Online Access: | http://www.dtic.mil/docs/citations/ADA615525 http://oai.dtic.mil/oai/oai?&verb=getRecord&metadataPrefix=html&identifier=ADA615525 |
Summary: | Sea-ice motion falls under the larger category of non-rigid motion analysis [Kambhamettu et al., 1994 1998, 2002]. The interdisciplinary field of non-rigid motion involves the understanding of three basic types of materials, namely, continuous, piece-wise continuous, and discrete particle motion. Depending on the scale, each of these descriptions applies to sea ice. At the large (basin) scale, sea ice has traditionally been regarded as a non-rigid Newtonian continuum and at the small scale it is regarded as a collection of discrete particles/floes. While great progress has been made in understanding these two outer scales of sea ice, the intermediate (mesoscale) of piece-wise continuous sea-ice motion is particularly difficult because it goes beyond the limits of its scale with very narrow (i.e. small scale) crack-like features stretching thousands of kilometers (i.e. basin scale). The added complexity of sea ice as a solid material at the air-sea boundary interface makes sea ice a challenging material to study. Understanding such complex behavior involves an interdisciplinary approach through which many other fields can reap the benefits. Our long-term goal is therefore to gain an understanding of mesoscale sea-ice processes and their interplay with large and small scale processes within the hierarchy of air-ice-sea processes. Our approach is a cross-disciplinary one, which is ideally suited to advance basic principles in the scientific community at large. |
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