Equilibria, Dynamics and Current Sheets Formation in Magnetically Confined Coronae

TL;DR

This paper investigates magnetic field equilibria and dynamics in solar and stellar coronae using a reduced MHD model, revealing how field asymmetry, current sheet formation, and energy dissipation depend on magnetic field strength and loop length.

Contribution

It introduces a novel analysis of reduced MHD equilibria, showing the relationship between magnetic field asymmetry, loop length, and energy dissipation in coronal magnetic fields.

Findings

Equilibria are asymmetric along the axial direction depending on field strength.

Fields below a certain threshold evolve quasi-statically without energy dissipation.

Stronger fields develop nonlinear dynamics and current sheets leading to energy release.

Abstract

The dynamics of magnetic fields in closed regions of solar and stellar coronae are investigated with a reduced magnetohydrodynamic (MHD) model in the framework of Parker scenario for coronal heating. A novel analysis of reduced MHD equilibria shows that their magnetic fields have an asymmetric structure in the axial direction with variation length-scale $z_\ell \sim \ell B_0/b$, where $B_0$ is the intensity of the strong axial guide field, $b$ that of the orthogonal magnetic field component, and $\ell$ the scale of $\mathbf{b}$. Equilibria are then quasi-invariant along the axial direction for variation scales larger than approximatively the loop length $z_\ell \gtrsim L_z$, and increasingly more asymmetric for smaller variation scales $z_\ell \lesssim L_z$. The $critical$ $length$ $z_\ell \sim L_z$ corresponds to the magnetic field intensity threshold $b \sim \ell B_0/L_z$. Magnetic fields stressed by photospheric motions cannot develop strong axial asymmetries. Therefore fields with intensities below such threshold evolve quasi-statically, readjusting to a nearby equilibrium, without developing nonlinear dynamics nor dissipating energy. But stronger fields cannot access their corresponding asymmetric equilibria, hence they are out-of-equilibrium and develop nonlinear dynamics. The subsequent formation of current sheets and energy dissipation is $necessary$ for the magnetic field to relax to equilibrium, since dynamically accessible equilibria have variation scales larger than the loop length $z_\ell \gtrsim L_z$, with intensities smaller than the threshold $b \lesssim \ell B_0/L_z$. The dynamical implications for magnetic fields of interest to solar and stellar coronae are investigated numerically and the impact on coronal physics discussed.