# FINMHD: an adaptive finite element code for magnetic reconnection and   plasmoid chains formation in Magnetohydrodynamics

**Authors:** Hubert Baty

arXiv: 1904.11173 · 2019-08-07

## TL;DR

This paper introduces FINMHD, an adaptive finite element code designed to simulate magnetic reconnection and plasmoid formation in magnetohydrodynamics, providing insights into fast energy release in astrophysical plasmas.

## Contribution

The paper presents a new adaptive finite element code specifically developed for 2D dissipative MHD simulations of magnetic reconnection and plasmoid chain formation.

## Key findings

- Transition from steady-state to plasmoid-dominated reconnection with increasing Lundquist number
- Code successfully captures formation of current sheets and magnetic islands
- Adaptive mesh enhances resolution of small-scale structures in simulations

## Abstract

Solving the problem of fast eruptive events in magnetically dominated astrophysical plasmas requires the use of particularly well adapted numerical tools. Indeed, the central mechanism based on magnetic reconnection is determined by a complex behavior with quasi-singular forming current layers enriched by their associated small scale magnetic islands called plasmoids. A new code for the solution of two dimensional dissipative magnetohydrodynamics (MHD) equations in cartesian geometry specifically developed to this end is thus presented. A current-vorticity formulation representative of an incompressible model is chosen in order to follow the formation of the current sheets and the ensuing magnetic reconnection process. A finite element discretization using triangles with quadratic basis functions on an unstructured grid is employed, and implemented via a highly adaptive characteristic- Galerkin scheme. The adaptivity of the code is illustrated on simplified test equations and finally for magnetic reconnection associated to the non linear development of the tilt instability between two repelling current channels. Varying the Lundquist number S, has allowed to study the transition between the steady-state Sweet-Parker reconnection regime (for S < 10^4) and plasmoids dominated reconnection one (for S > 10^5). The implications for the understanding of the mechanism explaining the fast conversion of free magnetic energy in astrophysical environments such as in solar corona are briefly discussed.

## Full text

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## Figures

31 figures with captions in the complete paper: https://tomesphere.com/paper/1904.11173/full.md

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Source: https://tomesphere.com/paper/1904.11173