The effect of shear flow on the resistive tearing instability

Alfred Mallet; Stefan Eriksson; Marc Swisdak; James Juno

doi:10.1017/S0022377825100858

The effect of shear flow on the resistive tearing instability

Alfred Mallet
, Stefan Eriksson
, Marc Swisdak
, James Juno

PPPL Computational Science

Research output: Contribution to journal › Article › peer-review

Abstract

We develop a new scaling theory for the resistive tearing mode instability of a current sheet with a strong shear flow across the layer. The growth rate decreases with increasing flow shear and is completely stabilized as the shear flow becomes Alfvénic: both in the constant-Ψ regime, as in previous results, but we also show that the growth rate is in fact suppressed more strongly in the nonconstant-Ψ regime. As a consequence, for sufficiently large flow shear, the maximum of the growth rate is always affected by the shear suppression, and the wavenumber at which this maximum growth rate is attained is an increasing function of the strength of the flow shear. These results may be important for the onset of reconnection in imbalanced MHD turbulence.

Original language	English (US)
Article number	E146
Journal	Journal of Plasma Physics
Volume	91
Issue number	5
DOIs	https://doi.org/10.1017/S0022377825100858
State	Published - Oct 30 2025

All Science Journal Classification (ASJC) codes

Condensed Matter Physics

Keywords

astrophysical plasmas
plasma instabilities
space plasma physics

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10.1017/S0022377825100858

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title = "The effect of shear flow on the resistive tearing instability",

abstract = "We develop a new scaling theory for the resistive tearing mode instability of a current sheet with a strong shear flow across the layer. The growth rate decreases with increasing flow shear and is completely stabilized as the shear flow becomes Alfv{\'e}nic: both in the constant-Ψ regime, as in previous results, but we also show that the growth rate is in fact suppressed more strongly in the nonconstant-Ψ regime. As a consequence, for sufficiently large flow shear, the maximum of the growth rate is always affected by the shear suppression, and the wavenumber at which this maximum growth rate is attained is an increasing function of the strength of the flow shear. These results may be important for the onset of reconnection in imbalanced MHD turbulence.",

keywords = "astrophysical plasmas, plasma instabilities, space plasma physics",

author = "Alfred Mallet and Stefan Eriksson and Marc Swisdak and James Juno",

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T1 - The effect of shear flow on the resistive tearing instability

AU - Mallet, Alfred

AU - Eriksson, Stefan

AU - Swisdak, Marc

AU - Juno, James

N1 - Publisher Copyright: © The Author(s), 2025.

PY - 2025/10/30

Y1 - 2025/10/30

N2 - We develop a new scaling theory for the resistive tearing mode instability of a current sheet with a strong shear flow across the layer. The growth rate decreases with increasing flow shear and is completely stabilized as the shear flow becomes Alfvénic: both in the constant-Ψ regime, as in previous results, but we also show that the growth rate is in fact suppressed more strongly in the nonconstant-Ψ regime. As a consequence, for sufficiently large flow shear, the maximum of the growth rate is always affected by the shear suppression, and the wavenumber at which this maximum growth rate is attained is an increasing function of the strength of the flow shear. These results may be important for the onset of reconnection in imbalanced MHD turbulence.

AB - We develop a new scaling theory for the resistive tearing mode instability of a current sheet with a strong shear flow across the layer. The growth rate decreases with increasing flow shear and is completely stabilized as the shear flow becomes Alfvénic: both in the constant-Ψ regime, as in previous results, but we also show that the growth rate is in fact suppressed more strongly in the nonconstant-Ψ regime. As a consequence, for sufficiently large flow shear, the maximum of the growth rate is always affected by the shear suppression, and the wavenumber at which this maximum growth rate is attained is an increasing function of the strength of the flow shear. These results may be important for the onset of reconnection in imbalanced MHD turbulence.

KW - astrophysical plasmas

KW - plasma instabilities

KW - space plasma physics

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DO - 10.1017/S0022377825100858

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JO - Journal of Plasma Physics

JF - Journal of Plasma Physics

IS - 5

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ER -

The effect of shear flow on the resistive tearing instability

Abstract

All Science Journal Classification (ASJC) codes

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