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Bibliographic Details
Main Authors: Lindberg, Sauli, MacTaggart, David
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2504.12936
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author Lindberg, Sauli
MacTaggart, David
author_facet Lindberg, Sauli
MacTaggart, David
contents Magnetic helicity is a quantity that underpins many theories of magnetic relaxation in electrically conducting fluids, both laminar and turbulent. Although much theoretical effort has been expended on magnetic fields that are everywhere tangent to their domain boundaries, many applications, both in astrophysics and laboratories, actually involve magnetic fields that are line-tied to the boundary, i.e. with a non-trivial normal component on the boundary. This modification of the boundary condition requires a modification of magnetic helicity, whose suitable replacement is called relative magnetic helicity. In this work, we investigate rigorously the behaviour of relative magnetic helicity under turbulent relaxation. In particular, we specify the normal component of the magnetic field on the boundary and consider the \emph{ideal limit} of resistivity tending to zero in order to model the turbulent evolution in the sense of Onsager's theory of turbulence. We show that relative magnetic helicity is conserved in this distinguished limit and that, for constant viscosity, the magnetic field can relax asymptotically to a magnetohydrostatic equilibrium.
format Preprint
id arxiv_https___arxiv_org_abs_2504_12936
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Relative magnetic helicity under turbulent relaxation
Lindberg, Sauli
MacTaggart, David
Plasma Physics
Analysis of PDEs
Magnetic helicity is a quantity that underpins many theories of magnetic relaxation in electrically conducting fluids, both laminar and turbulent. Although much theoretical effort has been expended on magnetic fields that are everywhere tangent to their domain boundaries, many applications, both in astrophysics and laboratories, actually involve magnetic fields that are line-tied to the boundary, i.e. with a non-trivial normal component on the boundary. This modification of the boundary condition requires a modification of magnetic helicity, whose suitable replacement is called relative magnetic helicity. In this work, we investigate rigorously the behaviour of relative magnetic helicity under turbulent relaxation. In particular, we specify the normal component of the magnetic field on the boundary and consider the \emph{ideal limit} of resistivity tending to zero in order to model the turbulent evolution in the sense of Onsager's theory of turbulence. We show that relative magnetic helicity is conserved in this distinguished limit and that, for constant viscosity, the magnetic field can relax asymptotically to a magnetohydrostatic equilibrium.
title Relative magnetic helicity under turbulent relaxation
topic Plasma Physics
Analysis of PDEs
url https://arxiv.org/abs/2504.12936