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Bibliographic Details
Main Authors: AlRefae, Talal, Calkins, Michael A.
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2508.08623
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author AlRefae, Talal
Calkins, Michael A.
author_facet AlRefae, Talal
Calkins, Michael A.
contents Heat transport in quasi-static magnetoconvection with a vertical magnetic field in a plane layer geometry is investigated with direct numerical simulations and asymptotic theory in the limit of large Chandrasekhar number ($Q$). It is shown that thermal and magnetic boundary layers with thickness $O(Q^{-1/6})$, of the same order as the horizontal scale of the convection, are persistent over the range of investigated parameters. Thermal boundary layer control of the heat transport indicates that the Nusselt number depends on $Q$, suggesting that no asymptotic state of heat transport independent of $Q$ occurs in this system. The magnetic boundary layers necessitate leading order modifications to the dominant vertical force balance as well as the amplitude of the horizontal induced magnetic field near the boundaries. The scaling behavior of the thermal boundary layer and resulting heat transport is found to be independent of the choice of mechanical and electromagnetic boundary conditions.
format Preprint
id arxiv_https___arxiv_org_abs_2508_08623
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Boundary layers in quasi-static magnetoconvection with a vertical field and their implications for heat transport
AlRefae, Talal
Calkins, Michael A.
Fluid Dynamics
Heat transport in quasi-static magnetoconvection with a vertical magnetic field in a plane layer geometry is investigated with direct numerical simulations and asymptotic theory in the limit of large Chandrasekhar number ($Q$). It is shown that thermal and magnetic boundary layers with thickness $O(Q^{-1/6})$, of the same order as the horizontal scale of the convection, are persistent over the range of investigated parameters. Thermal boundary layer control of the heat transport indicates that the Nusselt number depends on $Q$, suggesting that no asymptotic state of heat transport independent of $Q$ occurs in this system. The magnetic boundary layers necessitate leading order modifications to the dominant vertical force balance as well as the amplitude of the horizontal induced magnetic field near the boundaries. The scaling behavior of the thermal boundary layer and resulting heat transport is found to be independent of the choice of mechanical and electromagnetic boundary conditions.
title Boundary layers in quasi-static magnetoconvection with a vertical field and their implications for heat transport
topic Fluid Dynamics
url https://arxiv.org/abs/2508.08623