# Inference of magnetic field strength and density from damped transverse   coronal waves

**Authors:** I. Arregui, M. Montes-Solis, A. Asensio Ramos

arXiv: 1903.05437 · 2019-05-08

## TL;DR

This paper develops a Bayesian approach to infer magnetic field strength and density in coronal structures from damped transverse waves, effectively handling uncertainties and incorporating observational data for improved estimates.

## Contribution

It introduces a Bayesian framework for inferring magnetic field strength from damped MHD kink oscillations, accounting for density uncertainties and damping effects.

## Key findings

- Magnetic field strength can be inferred accurately despite unknown densities.
- Including observational density data constrains the posterior estimates.
- Damping information has minimal impact on magnetic field inference.

## Abstract

A classic application of coronal seismology uses transverse oscillations of waveguides to obtain estimates of the magnetic field strength. The procedure requires information on the density of the structures. Often, it ignores the damping of the oscillations. We computed marginal posteriors for parameters such as the waveguide density; the density contrast; the transverse inhomogeneity length-scale; and the magnetic field strength, under the assumption that the oscillations can be modelled as standing magnetohydrodynamic (MHD) kink modes damped by resonant absorption. Our results show that the magnetic field strength can be properly inferred, even if the densities inside and outside the structure are largely unknown. Incorporating observational estimates of plasma density further constrains the obtained posteriors. The amount of information one is willing to include (a priori) for the density and the density contrast influences their corresponding posteriors, but very little the inferred magnetic field strength. The decision to include or leave out the information on the damping and the damping time-scales have a minimal impact on the obtained magnetic field strength. In contrast to the classic method which provides with numerical estimates with error bars or possible ranges of variation for the magnetic field strength, Bayesian methods offer the full distribution of plausibility over the considered range of possible values. The methods are applied to available datasets of observed transverse loop oscillations, can be extended to prominence fine structures or chromospheric spicules and implemented to propagating waves in addition to standing oscillations.

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Source: https://tomesphere.com/paper/1903.05437