The multiphase physics of sea ice: a review for model developers

Rather than being solid throughout, sea ice contains liquid brine inclusions, solid salts, microalgae, trace elements, gases, and other impurities which all exist in the interstices of a porous, solid ice matrix. This multiphase structure of sea ice arises from the fact that the salt that exists in...

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Bibliographic Details
Published in:The Cryosphere
Main Authors: Hunke, E.C., Notz, D., Turner, A.K., Vancoppenolle, Martin
Other Authors: Los Alamos, New Mexico, USA - Los Alamos National Laboratory, UCL - SST/ELI/ELIC - Earth & Climate, Hamburg, Germany - Max Planck Institute for Meteorology
Format: Article in Journal/Newspaper
Language:English
Published: Copernicus GmbH 2011
Subjects:
CISM
1443
Sea ice
The Cryosphere
The Cryosphere Discussions
Online Access:http://hdl.handle.net/2078.1/93253
https://doi.org/10.5194/tc-5-989-2011
Description
Summary:Rather than being solid throughout, sea ice contains liquid brine inclusions, solid salts, microalgae, trace elements, gases, and other impurities which all exist in the interstices of a porous, solid ice matrix. This multiphase structure of sea ice arises from the fact that the salt that exists in seawater cannot be incorporated into lattice sites in the pure ice component of sea ice, but remains in liquid solution. Depending on the ice permeability (determined by temperature, salinity and gas content), this brine can drain from the ice, taking other sea ice constituents with it. Thus, sea ice salinity and microstructure are tightly interconnected and play a signiï¬cant role in polar ecosystems and climate. As large-scale climate modeling efforts move toward “earth system†simulations that include biological and chemical cycles, renewed interest in the multiphase physics of sea ice has strengthened research initiatives to observe, understand and model this complex system. This review article provides an overview of these efforts, highlighting known difï¬culties and requisite observations for further progress in the ï¬eld. We focus on mushy layer theory, which describes general multiphase materials, and on numerical approaches now being explored to model the multiphase evolution of sea ice and its interaction with chemical, biological and climate systems.

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