Coronal Alfven speeds in an isothermal atmosphere I. Global properties

TL;DR

This study models the coronal Alfven speeds in the solar atmosphere using force-free magnetic fields and isothermal plasma assumptions, revealing their dependence on magnetic configuration and implications for solar eruptive phenomena.

Contribution

It provides a comprehensive statistical analysis of magnetic field strength and Alfven speeds in active regions, highlighting their variation with height and magnetic topology.

Findings

Most magnetic flux is within 50 Mm of the photosphere.

Alfven speeds can reach up to 100,000 km/s in the corona.

Flaring regions exhibit Alfven speeds above 5000 km/s.

Abstract

Estimating Alfven speeds is of interest in modelling the solar corona, studying the coronal heating problem and understanding the initiation and propagation of coronal mass ejections (CMEs). We assume here that the corona is in a magnetohydrostatic equilibrium and that, because of the low plasma beta, one may decouple the magnetic forces from pressure and gravity. The magnetic field is then described by a force-free field for which we perform a statistical study of the magnetic field strength with height for four different active regions. The plasma along each field line is assumed to be in a hydrostatic equilibrium. As a first approximation, the coronal plasma is assumed to be isothermal with a constant or varying gravity with height. We study a bipolar magnetic field with a ring distribution of currents, and apply this method to four active regions associated with different eruptive events. By studying the global properties of the magnetic field strength above active regions, we conclude that (i) most of the magnetic flux is localized within 50 Mm of the photosphere, (ii) most of the energy is stored in the corona below 150 Mm, (iii) most of the magnetic field strength decays with height for a nonlinear force-free field slower than for a potential field. The Alfven speed values in an isothermal atmosphere can vary by two orders of magnitude (up to 100000 km/s). The global properties of the Alfven speed are sensitive to the nature of the magnetic configuration. For an active region with highly twisted flux tubes, the Alfven speed is significantly increased at the typical height of the twisted flux bundles; in flaring regions, the average Alfven speeds are above 5000 km/s and depart strongly from potential field values.