Effect of in-plane shear flow on the magnetic island coalescence instability

Mahapatra, Jagannath; Bokshi, Arkaprava; Ganesh, R.; Sen, Abhijit

doi:10.1063/5.0046225

Cited by 4 publications

(1 citation statement)

References 39 publications

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“…However, the focus has been predominantly on plasma energization. In the nonrelativistic regime, the shear flow effects on reconnection dynamics are more well studied (La Haye et al 2010;Nakamura et al 2013;Mahapatra et al 2021;Paul & Vaidya 2021). It has been shown that shear flows have a stabilizing effect on the tearing instability and can decrease the reconnection rate in the nonlinear stage.…”

Section: Introductionmentioning

confidence: 99%

Conditions for Relativistic Magnetic Reconnection under the Presence of Shear Flow and Guide Field

Peery,

Liu,

2024

ApJ

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The scaling of the relativistic reconnection outflow speed is studied in the presence of both shear flows parallel to the reconnecting magnetic fields and guide fields pointing out of the reconnection plane. In nonrelativistic reconnection, super-Alfvénic shear flows have been found to suppress reconnection. We extend the analytical model of this phenomenon to the relativistic regime and find similar behavior, which is confirmed by particle-in-cell simulations. Unlike the nonrelativistic limit, the addition of a guide field lowers the in-plane Alfvén velocity, contributing to slower outflow jets and the more efficient suppression of reconnection in strongly magnetized plasmas.

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Section: Introductionmentioning

confidence: 99%

Conditions for Relativistic Magnetic Reconnection under the Presence of Shear Flow and Guide Field

Peery,

Liu,

2024

ApJ

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Scaling of reconnection parameters in magnetic island coalescence: Role of in-plane shear flow

2022

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A 2D incompressible viscoresistive-MHD model [Mahapatra et al., Phys. Plasmas 28, 072103 (2021)] is used to study the scaling of reconnection parameters in the magnetic island coalescence problem under two interesting scenarios. First, the effect of changing island half-width at a fixed system size is investigated. As the island half-width increases, the total magnetic flux content of the islands increases, resulting in an increase in upstream magnetic field, upstream velocity field, and unnormalized reconnection rate. However, the downstream magnetic field, current sheet length and normalized reconnection rate (normalized to the upstream magnetic field and upstream Alfvénic velocity) remain independent of it. Interestingly, the reconnection rate is found to be different from the upstream to downstream velocity ratio as well as from the aspect ratio of the current sheet, as opposed to the findings of the Sweet–Parker model. Second, the in-plane shear flow effects are studied, keeping the island width and system size fixed. Here, thickness and length of the current sheet, the upstream magnetic and velocity field components, reconnection rate and time, current sheet inclination angle with shear flow length scale, and amplitude are calculated. Interestingly, the inclination angle of the current sheet and the diffusion region are found to be different, and the differences are more in stronger shear flows. These results are significantly different from the Harris sheet setup with shear flow.

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Coupling of ‘cold’ electron plasma wave via stationary ion inhomogeneity to the plasma bulk

Pandey¹,

Mahapatra²,

Ganesh³

2022

Phys. Scr.

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Using high resolution kinetic (VPPM-OMP 1.0) and fluid (BOUT++) solvers, evolution of long-wavelength electron plasma wave (EPW) in the presence of stationary periodic ion background non-uniformity is investigated. Mode coupling dynamics between long-wavelength EPW mode of scale k and ion inhomogeneity of scale k 0 is illustrated. Validity of well known Bessel function J n (x) scaling in the cold plasma approximation (i.e., when phase velocity ω/k v thermal ) alongwith the effect of ion inhomogeneity amplitude (A) on temporal evolution of energy density in the long-wavelength EPW mode is investigated. Effect of finite system sizes on the Bessel J n (x) scaling is examined and scaling law for τ F M i.e the time required to attain first minimum of energy density of the corresponding perturbed mode (also called phase mixing time for k −→ 0 modes) versus ion inhomogeneity amplitude A obtained from both kinetic and fluid solutions for each of the cases studied, alongwith some major differences in τ F M scaling for small system sizes is also reported.

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Effect of in-plane shear flow on the magnetic island coalescence instability

Cited by 4 publications

References 39 publications

Conditions for Relativistic Magnetic Reconnection under the Presence of Shear Flow and Guide Field

Conditions for Relativistic Magnetic Reconnection under the Presence of Shear Flow and Guide Field

Scaling of reconnection parameters in magnetic island coalescence: Role of in-plane shear flow

Coupling of ‘cold’ electron plasma wave via stationary ion inhomogeneity to the plasma bulk

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