Insights into brine dynamics and sea ice desalination from a 1-D model study of gravity drainage

We study gravity drainage using a new 1‐D, multiphase sea ice model. A parametrization of gravity drainage based on the convective nature of gravity drainage is introduced, whose free parameters are determined by optimizing model output against laboratory measurements of sea ice salinity evolution....

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Bibliographic Details
Published in:Journal of geophysical research. Oceans 2013-07, Vol.118 (7), p.3370-3386
Main Authors: Griewank, Philipp J., Notz, Dirk
Format: Article
Language:English
Subjects:
binary alloy solidification
Boundary conditions
brine fluxes
Brines
Desalination
Drainage
Drainage measurement
Earth, ocean, space
Exact sciences and technology
External geophysics
Geophysics
Global warming
Gravitation
gravity drainage
Ice
Marine
Mathematical models
Parametrization
Physics of the oceans
Salinity
Sea ice
Surface temperature
Thermal resistance
thermodynamics
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Summary:We study gravity drainage using a new 1‐D, multiphase sea ice model. A parametrization of gravity drainage based on the convective nature of gravity drainage is introduced, whose free parameters are determined by optimizing model output against laboratory measurements of sea ice salinity evolution. Optimal estimates of the free parameters as well as the parametrization performance remain stable for vertical grid resolutions from 1 to 30 mm. We find a strong link between sea ice growth rate and bulk salinity for constant boundary conditions but only a weak link for more realistic boundary conditions. We also demonstrate that surface warming can trigger brine convection over the whole ice layer. Over a growth season, replacing the convective parametrization with constant initial salinities leads to an overall 3% discrepancy of stored energy, thermal resistance, and salt release. We also derive from our convective parametrization a simplified, numerically cheap and stable gravity‐drainage parametrization. This parametrization results in an approximately 1% discrepancy of stored energy, thermal resistance, and salt release compared to the convective parametrization. A similarly low discrepancy to our complex parametrization can be reached by simply prescribing a depth‐dependent salinity profile. Key Points We present a physically consistent 1D parametrization of gravity drainage. We simulate warming induced full‐depth desalination. Gravity drainage influences long‐term sea‐ice evolution.
ISSN:2169-9275
2169-9291
DOI:10.1002/jgrc.20247