The challenges of modelling microphysics: ambipolar diffusion, chemistry, and cosmic rays in MHD shocks

From molecular clouds to protoplanetary disks, non-ideal magnetic effects are important in many astrophysical environments. Indeed, in star and disk formation processes, it has become clear that these effects are critical to the evolution of the system. The efficacy of non-ideal effects are, however...

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Veröffentlicht in:	arXiv.org 2019-01
Hauptverfasser:	Grassi, T, Padovani, M, Ramsey, J P, Galli, D, Vaytet, N, Ercolano, B, Haugboelle, T
Format:	Artikel
Sprache:	eng
Schlagworte:	Ambipolar diffusion Astrochemistry Computational fluid dynamics Computer simulation Cosmic rays Disks Magnetic effects Magnetohydrodynamics Microphysics Molecular clouds Organic chemistry Physics - Astrophysics of Galaxies Planet formation Protoplanets Shock waves Space telescopes Time dependence
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creator	Grassi, T Padovani, M Ramsey, J P Galli, D Vaytet, N Ercolano, B Haugboelle, T
description	From molecular clouds to protoplanetary disks, non-ideal magnetic effects are important in many astrophysical environments. Indeed, in star and disk formation processes, it has become clear that these effects are critical to the evolution of the system. The efficacy of non-ideal effects are, however, determined by the complex interplay between magnetic fields, ionising radiation, cosmic rays, microphysics, and chemistry. In order to understand these key microphysical parameters, we present a one-dimensional non-ideal magnetohydrodynamics code and apply it to a model of a time-dependent, oblique, magnetic shock wave. By varying the microphysical ingredients of the model, we find that cosmic rays and dust play a major role, and that, despite the uncertainties, the inclusion of microphysics is essential to obtain a realistic outcome in magnetic astrophysical simulations.
doi_str_mv	10.48550/arxiv.1901.00504
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subjects	Ambipolar diffusion Astrochemistry Computational fluid dynamics Computer simulation Cosmic rays Disks Magnetic effects Magnetohydrodynamics Microphysics Molecular clouds Organic chemistry Physics - Astrophysics of Galaxies Planet formation Protoplanets Shock waves Space telescopes Time dependence
title	The challenges of modelling microphysics: ambipolar diffusion, chemistry, and cosmic rays in MHD shocks
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