Saved in:
Bibliographic Details
Main Authors: Wang, Rachel, Ji, Hantao, Robbins, Adam, Bergstedt, Kendra, Ahmadi, Narges, Ergun, Robert, Chen, Li-Jen, Yoo, Jongsoo, Shi, Peiyun, Doke, Yuka
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2605.29244
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866916058335543296
author Wang, Rachel
Ji, Hantao
Robbins, Adam
Bergstedt, Kendra
Ahmadi, Narges
Ergun, Robert
Chen, Li-Jen
Yoo, Jongsoo
Shi, Peiyun
Doke, Yuka
author_facet Wang, Rachel
Ji, Hantao
Robbins, Adam
Bergstedt, Kendra
Ahmadi, Narges
Ergun, Robert
Chen, Li-Jen
Yoo, Jongsoo
Shi, Peiyun
Doke, Yuka
contents Magnetic reconnection is a ubiquitous plasma phenomenon that plays a critical role in particle heating and energization. During reconnection, the topology of magnetic field rearranges, depositing energy into the surrounding plasma through bulk flow, thermal heating, or non-thermal particle acceleration. While the pathways of this transformation from magnetic energy into kinetic have been studied extensively in recent years through theoretical or case-by-case observations, comprehensive statistical studies remain limited. In this paper, we present a statistical investigation using data from the Magnetospheric Multiscale (MMS) mission, and detail the particle energization mechanisms in magnetic structures found near reconnecting regions in turbulent Earth's magnetotail. We find that electrons with motion perpendicular to the magnetic field dominate $\vec{j}\cdot\vec{E}$ dissipation. In contrast to the conventional picture of unidirectional energy transfer to particles by laminar two-dimensional (2D) reconnection, we find that energy exchange within magnetic structures during turbulent reconnection tends to be bidirectional with only a small positive bias from electromagnetic fields to particles. Specific electron energization mechanisms are quantified, including those due to parallel electric field, Fermi energization from curvature drift, betatron heating from magnetic field inhomogeneity, and polarization drift.
format Preprint
id arxiv_https___arxiv_org_abs_2605_29244
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Statistical study of energy dissipation in magnetic structures during turbulent reconnection in the Earth's magnetotail
Wang, Rachel
Ji, Hantao
Robbins, Adam
Bergstedt, Kendra
Ahmadi, Narges
Ergun, Robert
Chen, Li-Jen
Yoo, Jongsoo
Shi, Peiyun
Doke, Yuka
Space Physics
Earth and Planetary Astrophysics
Magnetic reconnection is a ubiquitous plasma phenomenon that plays a critical role in particle heating and energization. During reconnection, the topology of magnetic field rearranges, depositing energy into the surrounding plasma through bulk flow, thermal heating, or non-thermal particle acceleration. While the pathways of this transformation from magnetic energy into kinetic have been studied extensively in recent years through theoretical or case-by-case observations, comprehensive statistical studies remain limited. In this paper, we present a statistical investigation using data from the Magnetospheric Multiscale (MMS) mission, and detail the particle energization mechanisms in magnetic structures found near reconnecting regions in turbulent Earth's magnetotail. We find that electrons with motion perpendicular to the magnetic field dominate $\vec{j}\cdot\vec{E}$ dissipation. In contrast to the conventional picture of unidirectional energy transfer to particles by laminar two-dimensional (2D) reconnection, we find that energy exchange within magnetic structures during turbulent reconnection tends to be bidirectional with only a small positive bias from electromagnetic fields to particles. Specific electron energization mechanisms are quantified, including those due to parallel electric field, Fermi energization from curvature drift, betatron heating from magnetic field inhomogeneity, and polarization drift.
title Statistical study of energy dissipation in magnetic structures during turbulent reconnection in the Earth's magnetotail
topic Space Physics
Earth and Planetary Astrophysics
url https://arxiv.org/abs/2605.29244