Particle acceleration with anomalous pitch angle scattering in 2D MHD reconnection simulations

TL;DR

This study investigates how pitch angle scattering influences particle acceleration in 2D MHD reconnection simulations, revealing that scattering rates tied to anomalous resistivity affect maximum energies and particle escape routes.

Contribution

It introduces the first analysis of pitch angle scattering effects in particle acceleration within 2D MHD reconnection, considering variable scattering rates related to anomalous resistivity.

Findings

Higher maximum energies with scattering compared to no scattering.

Dependent scattering rates reduce high-energy particle counts.

Scattering increases particle escape through outflows.

Abstract

The conversion of magnetic energy into other forms during solar flares is one of the outstanding open problems in solar physics. It is generally accepted that magnetic reconnection plays a crucial role in these conversion processes. To achieve the rapid energy release required in solar flares, an anomalous resistivity, orders of magnitude higher than the Spitzer resistivity, is often used in MHD simulations of reconnection. Spitzer resistivity is based on Coulomb scattering, which becomes negligible at the high energies achieved by accelerated particles. As a result, simulations of particle acceleration in reconnection events are often performed in the absence of any interaction between accelerated particles and any background plasma. This need not be the case for scattering associated with anomalous resistivity caused by turbulence within solar flares, as the higher resistivity implies an elevated scattering rate. We present results of test particle calculations, with and without pitch angle scattering, subject to fields derived from MHD simulations of two-dimensional (2D) X-point reconnection. Scattering rates proportional to the ratio of the anomalous resistivity to the local Spitzer resistivity, as well as at fixed values, are considered. Pitch angle scattering, which is independent of the anomalous resistivity, causes higher maximum energies in comparison to those obtained without scattering. Scattering rates which are dependent on the local anomalous resistivity tend to produce fewer highly energised particles due to weaker scattering in the separatrices, even though scattering in the current sheet may be stronger when compared to resistivity-independent scattering. Strong scattering also causes an increase in the number of particles exiting the computational box in the reconnection outflow region, as opposed to along the separatrices as is the case in the absence of scattering.