Nonlinear wave damping by Kelvin-Helmholtz instability induced turbulence

TL;DR

This paper investigates how Kelvin-Helmholtz instability-induced turbulence affects the nonlinear damping of kink waves in coronal loops, revealing stages of turbulence growth and decay that differ from linear models.

Contribution

It introduces a two-stage model of KHi turbulence evolution on nonlinear kink waves, providing accurate predictions for damping and heating beyond linear theory.

Findings

KHi turbulence growth follows a t-linear model in the initial stage.

Turbulent energy decay approximately follows a t^{-2} law.

Damping profiles differ from those predicted by linear wave theory.

Abstract

Magnetohydrodynamic kink waves naturally form as a consequence of perturbations to a structured medium, for example transverse oscillations of coronal loops. Linear theory has provided many insights in the evolution of linear oscillations, and results from these models are often applied to infer information about the solar corona from observed wave periods and damping times. However, simulations show that nonlinear kink waves can host the Kelvin-Helmholtz instability (KHi) which subsequently creates turbulence in the loop, dynamics which are beyond linear models. In this paper we investigate the evolution of KHi-induced turbulence on the surface of a flux tube where a non-linear fundamental kink-mode has been excited. We control our numerical experiment so that we induce the KHi without exciting resonant absorption. We find two stages in the KHi turbulence dynamics. In the first stage, we show that the classic model of a KHi turbulent layer growing $\propto t$is applicable. We adapt this model to make accurate predictions for damping of the oscillation and turbulent heating as a consequence of the KHi dynamics. In the second stage, the now dominant turbulent motions are undergoing decay. We find that the classic model of energy decay proportional to $t^{-2}$ approximately holds and provides an accurate prediction of the heating in this phase. Our results show that we can develop simple models for the turbulent evolution of a non-linear kink wave, but the damping profiles produced are distinct from those of linear theory that are commonly used to confront theory and observations.