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A computational model for exploring particle acceleration during reconnection in macro-scale systems

A new computational model is presented suitable for exploring the self-consistent production of energetic electrons during magnetic reconnection in macroscale systems. The equations are based on the recent discovery that parallel electric fields are ineffective drivers of energetic particles during...

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Published in:	arXiv.org 2018-12
Main Authors:	Drake, J F, Arnold, H, Swisdak, M, Dahlin, J T
Format:	Article
Language:	English
Subjects:	Anisotropy Computational fluid dynamics Dynamic stability Electric fields Energetic particles Fluid flow Magnetohydrodynamics Mathematical models Particle acceleration Particle in cell technique Particle physics Throttling Wave propagation
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creator	Drake, J F Arnold, H Swisdak, M Dahlin, J T
description	A new computational model is presented suitable for exploring the self-consistent production of energetic electrons during magnetic reconnection in macroscale systems. The equations are based on the recent discovery that parallel electric fields are ineffective drivers of energetic particles during reconnection so that the kinetic scales which control the development of such fields can be ordered out of the equations. The resulting equations consist of a magnetohydrodynamic (MHD) backbone with the energetic component represented by macro-particles described by the guiding center equations. Crucially, the energetic component feeds back on the MHD equations so that the total energy of the MHD fluid and the energetic particles is conserved. The equations correctly describe the firehose instability, whose dynamics plays a key role in throttling reconnection and in controlling the spectra of energetic particles. The results of early tests of the model, including the propagation of Alfven waves in a system with pressure anisotropy and the growth of firehose modes, establish that the basic algorithm is stable and produces reliable physics results in preparation for further benchmarking with particle-in-cell models of reconnection.
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subjects	Anisotropy Computational fluid dynamics Dynamic stability Electric fields Energetic particles Fluid flow Magnetohydrodynamics Mathematical models Particle acceleration Particle in cell technique Particle physics Throttling Wave propagation
title	A computational model for exploring particle acceleration during reconnection in macro-scale systems
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