Electron-Scale Reconnection in Three-Dimensional Shock Turbulence

J. Ng; L. J. Chen; N. Bessho; J. Shuster; B. Burkholder; J. Yoo

doi:10.1029/2022GL099544

Electron-Scale Reconnection in Three-Dimensional Shock Turbulence

J. Ng, L. J. Chen, N. Bessho, J. Shuster, B. Burkholder, J. Yoo

PPPL Discovery Plasma Science

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

20 Scopus citations

Abstract

Magnetic reconnection has been observed in the transition region of quasi-parallel shocks. In this work, the particle-in-cell method is used to simulate three-dimensional reconnection in a quasi-parallel shock. The shock transition region is turbulent, leading to the formation of reconnecting current sheets with various orientations. Two reconnection sites with weak and strong guide fields are studied, and it is shown that reconnection is fast and transient. Reconnection sites are characterized using diagnostics including electron flows and magnetic flux transport. In contrast to two-dimensional simulations, weak guide field reconnection is realized. Furthermore, the current sheets in these events form in a direction almost perpendicular to those found in two-dimensional simulations, where the reconnection geometry is constrained.

Original language	English (US)
Article number	e2022GL099544
Journal	Geophysical Research Letters
Volume	49
Issue number	15
DOIs	https://doi.org/10.1029/2022GL099544
State	Published - Aug 16 2022

All Science Journal Classification (ASJC) codes

Geophysics
General Earth and Planetary Sciences

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10.1029/2022GL099544

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title = "Electron-Scale Reconnection in Three-Dimensional Shock Turbulence",

abstract = "Magnetic reconnection has been observed in the transition region of quasi-parallel shocks. In this work, the particle-in-cell method is used to simulate three-dimensional reconnection in a quasi-parallel shock. The shock transition region is turbulent, leading to the formation of reconnecting current sheets with various orientations. Two reconnection sites with weak and strong guide fields are studied, and it is shown that reconnection is fast and transient. Reconnection sites are characterized using diagnostics including electron flows and magnetic flux transport. In contrast to two-dimensional simulations, weak guide field reconnection is realized. Furthermore, the current sheets in these events form in a direction almost perpendicular to those found in two-dimensional simulations, where the reconnection geometry is constrained.",

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T1 - Electron-Scale Reconnection in Three-Dimensional Shock Turbulence

AU - Ng, J.

AU - Chen, L. J.

AU - Bessho, N.

AU - Shuster, J.

AU - Burkholder, B.

AU - Yoo, J.

PY - 2022/8/16

Y1 - 2022/8/16

N2 - Magnetic reconnection has been observed in the transition region of quasi-parallel shocks. In this work, the particle-in-cell method is used to simulate three-dimensional reconnection in a quasi-parallel shock. The shock transition region is turbulent, leading to the formation of reconnecting current sheets with various orientations. Two reconnection sites with weak and strong guide fields are studied, and it is shown that reconnection is fast and transient. Reconnection sites are characterized using diagnostics including electron flows and magnetic flux transport. In contrast to two-dimensional simulations, weak guide field reconnection is realized. Furthermore, the current sheets in these events form in a direction almost perpendicular to those found in two-dimensional simulations, where the reconnection geometry is constrained.

AB - Magnetic reconnection has been observed in the transition region of quasi-parallel shocks. In this work, the particle-in-cell method is used to simulate three-dimensional reconnection in a quasi-parallel shock. The shock transition region is turbulent, leading to the formation of reconnecting current sheets with various orientations. Two reconnection sites with weak and strong guide fields are studied, and it is shown that reconnection is fast and transient. Reconnection sites are characterized using diagnostics including electron flows and magnetic flux transport. In contrast to two-dimensional simulations, weak guide field reconnection is realized. Furthermore, the current sheets in these events form in a direction almost perpendicular to those found in two-dimensional simulations, where the reconnection geometry is constrained.

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ER -

Electron-Scale Reconnection in Three-Dimensional Shock Turbulence

Abstract

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