Boosting magnetic reconnection by viscosity and thermal conduction

Minoshima, Takashi; Miyoshi, Tetsuya; Imada, Shinsuke

doi:10.1063/1.4959852

Cited by 3 publications

(2 citation statements)

References 43 publications

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“…These Prandtl numbers match a condition that corresponds to a boost in magnetic reconnection. Minoshima et al (2016) perform 2D single-fluid MHD simulations that include heat conduction and viscosity effects, and find that a small fluid Prandtl number and a large magnetic Prandtl number (Pr < 1 and Pr m > 1) preferentially boosts magnetic reconnection. Their interpretation is that having the viscosity stronger than the resistivity (Pr m > 1) results in a broader vortex layer than the current sheet layer, and the quadrupolar vortex excited in the vortex layer efficiently carries the upstream magnetic flux toward the reconnection region and the reconnection rate increases.…”

Section: Pui-induced Turbulence Heat Conduction and Viscositymentioning

confidence: 99%

Pickup Ion–Mediated Magnetic Reconnection in the Outer Heliosphere

Nakanotani

Zank

Zhao

2023

ApJL

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Pickup ions (PUIs) play a crucial role in the heliosphere, contributing to the mediation of large-scale structures such as the distant solar wind, the heliospheric termination shock, and the heliopause. While magnetic reconnection is thought to be a common process in the heliosphere due to the presence of heliospheric current sheets, it is poorly understood how PUIs might affect the evolution of magnetic reconnection. Although it is reasonable to suppose that PUIs decrease the reconnection rate since the plasma beta becomes much larger than 1 when PUIs are included, we show for the first time that such a supposition is invalid and that PUI-induced turbulence, heat conduction, and viscosity can preferentially boost magnetic reconnection in heliospheric current sheets in the distant solar wind. This suggests that it is critical to include the effect of the turbulence, heat conduction, and viscosity caused by PUIs to understand the dynamics of magnetic reconnection in the outer heliosphere.

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Section: Pui-induced Turbulence Heat Conduction and Viscositymentioning

confidence: 99%

Pickup Ion–Mediated Magnetic Reconnection in the Outer Heliosphere

Nakanotani

Zank

Zhao

2023

ApJL

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“…The nonlinearity of the numerical resistivity in the CUCT-AA method would be relatively weak, and it results in the elongated current sheet and the subsequent plasmoid formation that is a resemblance to the tearing instability for a uniform resistivity (Biskamp 1986). In order to test this hypothesis, we apply the schemes to the visco-resistive MHD equations (Minoshima et al 2016), and solve the same problem. Kinematic viscosity and resistivity coefficients, ν and η, are assumed constant and uniform, and the corresponding kinetic and magnetic Reynolds numbers are V A λ/ν = V A λ/η = 10 3 .…”

Section: Magnetic Reconnectionmentioning

confidence: 99%

A High-order Weighted Finite Difference Scheme with a Multistate Approximate Riemann Solver for Divergence-free Magnetohydrodynamic Simulations

Minoshima

Miyoshi

Matsumoto

2019

ApJS

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We design a conservative finite difference scheme for ideal magnetohydrodynamic simulations that attains high-order accuracy, shock-capturing, and divergence-free condition of the magnetic field. The scheme interpolates pointwise physical variables from computational nodes to midpoints through a high-order nonlinear weighted average. The numerical flux is evaluated at the midpoint by a multi-state approximate Riemann solver for correct upwinding, and its spatial derivative is approximated by a high-order linear central difference to update the variables with designed order of accuracy and conservation. The magnetic and electric fields are defined at staggered grid points employed in the Constrained Transport (CT) method by Evans & Hawley (1988). We propose a new CT variant, in which the staggered electric field is evaluated so as to be consistent with the base one-dimensional Riemann solver and the staggered magnetic field is updated to be divergence-free as designed high-order finite difference representation. We demonstrate various benchmark tests to measure the performance of the present scheme. We discuss the effect of the choice of interpolation methods, Riemann solvers, and the treatment for the divergence-free condition on the quality of numerical solutions in detail.

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Oscillatory regimes of compressible 2.5D viscous linear magnetic reconnection

McMahon

2019

Physics of Plasmas

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We investigate the dynamics and energetics of magnetic reconnection in a general linear magnetohydrodynamic (MHD) model. Our investigation is threefold: First, we formulate a generalized 2.5D linearized MHD system in the presence of viscous, pressure, collisionless, and axial magnetic effects. Second, we find, in accordance with previous studies, that viscous effects, while reducing the rate of reconnection, boost the rate of total energy release. Moreover, viscous dissipation, as opposed to resistive dissipation, is unlikely to be impeded by pressure forces. Third, we compare two different equilibrium axial magnetic field profiles. One profile emulates a quasiseparatrix layer and the other profile emulates a 3D null point. In 2.5D, these profiles actually correspond to a hyperbolic field threaded by an axial field and a null line, respectively. We show evidence that fast reconnection is only attainable in the presence of a null.

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Boosting magnetic reconnection by viscosity and thermal conduction

Cited by 3 publications

References 43 publications

Pickup Ion–Mediated Magnetic Reconnection in the Outer Heliosphere

Pickup Ion–Mediated Magnetic Reconnection in the Outer Heliosphere

A High-order Weighted Finite Difference Scheme with a Multistate Approximate Riemann Solver for Divergence-free Magnetohydrodynamic Simulations

Oscillatory regimes of compressible 2.5D viscous linear magnetic reconnection

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