Homogenization for convection-enhanced thermal transport in sea ice

Sea ice regulates heat exchange between the ocean and atmosphere in Earth’s polar regions. The thermal conductivity of sea ice governs this exchange, and is a key parameter in climate modelling. However, it is challenging to measure and predict due to its sensitive dependence on temperature, salinit...

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Bibliographic Details
Published in:Proceedings of the Royal Society A: Mathematical, Physical and Engineering Sciences
Main Authors: Kraitzman, Noa, Hardenbrook, Rebecca, Dinh, Huy, Murphy, N. Benjamin, Cherkaev, Elena, Zhu, Jingyi, Golden, Kenneth M.
Format: Article in Journal/Newspaper
Language:English
Published: 2024
Subjects:
thermal conductivity
sea ice
advection diffusion processes
convective fluid flow
Stieltjes integrals
Padé approximants
advection-diffusion processes
Sea ice
Online Access:https://researchers.mq.edu.au/en/publications/9af327a8-4ea8-4399-803f-8b1b921840a5
https://doi.org/10.1098/rspa.2023.0747
https://research-management.mq.edu.au/ws/files/363053761/kraitzman_et_al_2024_homogenization_for_convection_enhanced_thermal_transport_in_sea_ice.pdf
http://www.scopus.com/inward/record.url?scp=85202782498&partnerID=8YFLogxK
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Summary:Sea ice regulates heat exchange between the ocean and atmosphere in Earth’s polar regions. The thermal conductivity of sea ice governs this exchange, and is a key parameter in climate modelling. However, it is challenging to measure and predict due to its sensitive dependence on temperature, salinity and brine microstructure. Moreover, as temperature increases, sea ice becomes permeable, and fluid can flow through the porous microstructure. While models for thermal diffusion through sea ice have been obtained, advective contributions to transport have not been considered theoretically. Here, we homogenize a multiscale advection–diffusion equation that models thermal transport through porous sea ice when fluid flow is present. We consider two-dimensional models of convective flow and use an integral representation to derive bounds on the thermal conductivity as a function of the Péclet number. These bounds guarantee enhancement in the thermal conductivity due to the added flow. Further, we relate the Péclet number to temperature, making these bounds useful for global climate models. Our analytic approach offers a mathematical theory which can not only improve predictions of atmosphere–ice–ocean heat exchanges in climate models, but can provide a theoretical framework for a range of problems involving advection–diffusion processes in various fields of application.

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