Conditions for Justifying Single-fluid Approximation for Charged and Neutral Dust Fluids and a Smoothed Particle Magnetohydrodynamics Method for Dust–Gas Mixture

We describe a numerical scheme for magnetohydrodynamics simulations of dust–gas mixture by extending smoothed particle magnetohydrodynamics. We employ the single-species particle approach to describe dust–gas mixture with several modifications from the previous studies. We assume that the charged an...

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Bibliographic Details
Published in:The Astrophysical journal 2021-06, Vol.913 (2), p.148
Main Authors: Tsukamoto, Y., Machida, M. N., Inutsuka, S.
Format: Article
Language:English
Subjects:
Approximation
Astrophysical dust processes
Astrophysics
Computational fluid dynamics
Context
Dust
Electric currents
Electromagnetic forces
Gas mixtures
Gravitational collapse
Magnetic fields
Magnetohydrodynamic simulation
Magnetohydrodynamical simulations
Magnetohydrodynamics
Mathematical analysis
Numerical schemes
Star formation
Terminal velocity
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Summary:We describe a numerical scheme for magnetohydrodynamics simulations of dust–gas mixture by extending smoothed particle magnetohydrodynamics. We employ the single-species particle approach to describe dust–gas mixture with several modifications from the previous studies. We assume that the charged and neutral dust can be treated as single-fluid, that the electromagnetic force acts on the gas, and that that acting on the charged dust is negligible. The validity of these assumptions in the context of protostar formation is not obvious and is extensively evaluated. By investigating the electromagnetic force and electric current with terminal velocity approximation, it is found that as the dust size increases, the contribution of dust to them becomes smaller and negligible. We conclude that our assumption that the electromagnetic force on the dusts is negligible is valid for the dust size with a d ≳ 10 μ m. On the other hand, they do not produce the numerical artifact for the dust a d ≲ 10 μ m in the envelope and disk, where the perfect coupling between gas and dust is realized. However, we also found that our assumptions may break down in outflow (or under an environment with very strong magnetic field and low density) for the dust a d ≲ 10 μ m. We conclude that our assumptions are valid in almost all cases where macroscopic dust dynamics is important in the context of protostar formation. We conduct numerical tests of dusty waves, dusty magnetohydrodynamics shocks, and gravitational collapse of magnetized cloud cores with our simulation code. The results show that our numerical scheme well reproduces the dust dynamics in the magnetized medium.
ISSN:0004-637X
1538-4357
DOI:10.3847/1538-4357/abf5db