Models of collisionless quasineutral solar wind current sheets

Sophie Boswell; Thomas Neukirch; Anton Artemyev; Ivan Vasko; Oliver Allanson

doi:10.1007/s11207-025-02551-8

Models of collisionless quasineutral solar wind current sheets

Sophie Boswell^*, Thomas Neukirch, Anton Artemyev, Ivan Vasko, Oliver Allanson

^*Corresponding author for this work

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

Abstract

In situ measurements of kinetic scale current sheets in the solar wind show that they are often approximately force-free although the plasma β is of order one. They frequently display systematic asymmetric and anti-correlated spatial variations of their particle density and temperature across the current sheet, leaving the plasma pressure essentially uniform. These observations of asymmetries have previously been modelled theoretically by adding additional terms to both the ion and electron distribution functions of self-consistent force-free collisionless current sheet models with constant density and temperature profiles. In this article we present the results of a modification of these models in which only the electron distribution function has an additional term, whereas the ion distribution function is kept as a thermal (Maxwellian) distribution function. In this case the nonlinear quasineutrality condition no longer has a simple analytical solution and therefore has to be solved alongside Ampère’s law. We find that while the magnetic field remains approximately force-free, the non-zero quasineutral electric field gives rise to an additional spatial substructure of the plasma density inside the current sheet. We briefly discuss the potential relation between our theoretical findings and current sheet observations.

Original language	English
Article number	142
Number of pages	18
Journal	Solar Physics
Volume	300
Issue number	10
DOIs	https://doi.org/10.1007/s11207-025-02551-8
Publication status	Published - 13 Oct 2025

Keywords

Electric currents and current sheets
Solar wind, theory
Plasma theory
Magnetic fields, models

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10.1007/s11207-025-02551-8Licence: CC BY

Boswell_2025_SP_Models-collisionless-quasineutral-solar-wind-sheets_CC
© The Author(s) 2025. This article is licensed under a Creative Commons Attribution 4.0 International License (https://creativecommons.org/licenses/by/4.0/), which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made.
Final published version, 1.27 MBLicence: CC BY

Solar and Magnetospheric Plasmas: Solar and Magnetospheric Plasmas: Theory and Application
Neukirch, T. (PI), Archontis, V. (CoI), De Moortel, I. (CoI), Hood, A. (CoI), Mackay, D. (CoI), Parnell, C. (CoI) & Wright, A. (CoI)
Science & Technology Facilities Council
1/04/22 → 31/03/25
Project: Standard
Solar and Magnetospheric: Solar and Magnetospheric Magnetohydrodynamics and Plasmas: Theory and Application
Hood, A. (PI), Archontis, V. (CoI), De Moortel, I. (CoI), Mackay, D. (CoI), Neukirch, T. (CoI), Parnell, C. (CoI) & Wright, A. (CoI)
Science & Technology Facilities Council
1/04/19 → 31/03/22
Project: Standard

Cite this

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title = "Models of collisionless quasineutral solar wind current sheets",

abstract = "In situ measurements of kinetic scale current sheets in the solar wind show that they are often approximately force-free although the plasma β is of order one. They frequently display systematic asymmetric and anti-correlated spatial variations of their particle density and temperature across the current sheet, leaving the plasma pressure essentially uniform. These observations of asymmetries have previously been modelled theoretically by adding additional terms to both the ion and electron distribution functions of self-consistent force-free collisionless current sheet models with constant density and temperature profiles. In this article we present the results of a modification of these models in which only the electron distribution function has an additional term, whereas the ion distribution function is kept as a thermal (Maxwellian) distribution function. In this case the nonlinear quasineutrality condition no longer has a simple analytical solution and therefore has to be solved alongside Amp{\`e}re{\textquoteright}s law. We find that while the magnetic field remains approximately force-free, the non-zero quasineutral electric field gives rise to an additional spatial substructure of the plasma density inside the current sheet. We briefly discuss the potential relation between our theoretical findings and current sheet observations.",

keywords = "Electric currents and current sheets, Solar wind, theory, Plasma theory, Magnetic fields, models",

author = "Sophie Boswell and Thomas Neukirch and Anton Artemyev and Ivan Vasko and Oliver Allanson",

note = "Funding: S.B. acknowledges support from the United Kingdom Research and Innovation (UKRI) Science and Technology Facilities Council (STFC) Doctoral Training Partnership Grant ST/X508779/1. T.N. acknowledges support by STFC Consolidated Grants ST/S000402/1 and ST/W001195/1. A.A. acknowledges support from NASA 80NSSC23K0658, 80NSSC22K0752. I.V. thanks RSF project No. 24-12-00457. O.A. would like to acknowledge support from the University of Birmingham, and also from the United Kingdom Research and Innovation (UKRI) Natural Environment Research Council (NERC) Independent Research Fellowship NE/V013963/1 and NE/V013963/2.",

year = "2025",

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doi = "10.1007/s11207-025-02551-8",

language = "English",

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journal = "Solar Physics",

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T1 - Models of collisionless quasineutral solar wind current sheets

AU - Boswell, Sophie

AU - Neukirch, Thomas

AU - Artemyev, Anton

AU - Vasko, Ivan

AU - Allanson, Oliver

N1 - Funding: S.B. acknowledges support from the United Kingdom Research and Innovation (UKRI) Science and Technology Facilities Council (STFC) Doctoral Training Partnership Grant ST/X508779/1. T.N. acknowledges support by STFC Consolidated Grants ST/S000402/1 and ST/W001195/1. A.A. acknowledges support from NASA 80NSSC23K0658, 80NSSC22K0752. I.V. thanks RSF project No. 24-12-00457. O.A. would like to acknowledge support from the University of Birmingham, and also from the United Kingdom Research and Innovation (UKRI) Natural Environment Research Council (NERC) Independent Research Fellowship NE/V013963/1 and NE/V013963/2.

PY - 2025/10/13

Y1 - 2025/10/13

N2 - In situ measurements of kinetic scale current sheets in the solar wind show that they are often approximately force-free although the plasma β is of order one. They frequently display systematic asymmetric and anti-correlated spatial variations of their particle density and temperature across the current sheet, leaving the plasma pressure essentially uniform. These observations of asymmetries have previously been modelled theoretically by adding additional terms to both the ion and electron distribution functions of self-consistent force-free collisionless current sheet models with constant density and temperature profiles. In this article we present the results of a modification of these models in which only the electron distribution function has an additional term, whereas the ion distribution function is kept as a thermal (Maxwellian) distribution function. In this case the nonlinear quasineutrality condition no longer has a simple analytical solution and therefore has to be solved alongside Ampère’s law. We find that while the magnetic field remains approximately force-free, the non-zero quasineutral electric field gives rise to an additional spatial substructure of the plasma density inside the current sheet. We briefly discuss the potential relation between our theoretical findings and current sheet observations.

AB - In situ measurements of kinetic scale current sheets in the solar wind show that they are often approximately force-free although the plasma β is of order one. They frequently display systematic asymmetric and anti-correlated spatial variations of their particle density and temperature across the current sheet, leaving the plasma pressure essentially uniform. These observations of asymmetries have previously been modelled theoretically by adding additional terms to both the ion and electron distribution functions of self-consistent force-free collisionless current sheet models with constant density and temperature profiles. In this article we present the results of a modification of these models in which only the electron distribution function has an additional term, whereas the ion distribution function is kept as a thermal (Maxwellian) distribution function. In this case the nonlinear quasineutrality condition no longer has a simple analytical solution and therefore has to be solved alongside Ampère’s law. We find that while the magnetic field remains approximately force-free, the non-zero quasineutral electric field gives rise to an additional spatial substructure of the plasma density inside the current sheet. We briefly discuss the potential relation between our theoretical findings and current sheet observations.

KW - Electric currents and current sheets

KW - Solar wind, theory

KW - Plasma theory

KW - Magnetic fields, models

U2 - 10.1007/s11207-025-02551-8

DO - 10.1007/s11207-025-02551-8

M3 - Article

SN - 0038-0938

VL - 300

JO - Solar Physics

JF - Solar Physics

IS - 10

M1 - 142

ER -

Models of collisionless quasineutral solar wind current sheets

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Solar and Magnetospheric Plasmas: Solar and Magnetospheric Plasmas: Theory and Application

Solar and Magnetospheric: Solar and Magnetospheric Magnetohydrodynamics and Plasmas: Theory and Application

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