Turbulent Energy Conversion Associated With Kinetic Microinstabilities in Earth's Magnetosheath

Harry C. Lewis; Julia E. Stawarz; Lorenzo Matteini; Luca Franci; Kristopher G. Klein; Robert T. Wicks; Chadi S. Salem; Timothy S. Horbury; Joseph H. Wang

doi:10.1029/2024GL112038

Turbulent Energy Conversion Associated With Kinetic Microinstabilities in Earth's Magnetosheath

Harry C. Lewis, Julia E. Stawarz, Lorenzo Matteini, Luca Franci, Kristopher G. Klein, Robert T. Wicks, Chadi S. Salem, Timothy S. Horbury, Joseph H. Wang

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

2 Scopus citations

Abstract

Plasma in Earth's magnetosheath rarely experiences interparticle collisions, so kinetic microinstabilities are thought to contribute to regulating the plasma thermodynamics. Instabilities excite waves and redistribute free energy in velocity space, reducing free energy in the velocity distribution function (VDF). Using 24 hr of data spread over 163 intervals of in situ magnetosheath observations by Magnetospheric Multiscale (MMS), we investigate signatures of energy conversion where the turbulent dynamics have locally distorted the VDFs into non-Maxwellian shapes, in the context of electron and ion temperature anisotropy driven instabilities. We find enhanced average energy conversion into the particles along instability boundaries, suggesting turbulence plays a role in redistributing free energy. In so doing, we quantify the energetics associated with unstable conditions for both species. This work provides insight into the open question of how specific plasma processes couple into the turbulent dynamics, ultimately leading to energy dissipation and particle energization in collisionless plasmas.

Original language	English (US)
Article number	e2024GL112038
Journal	Geophysical Research Letters
Volume	51
Issue number	24
DOIs	https://doi.org/10.1029/2024GL112038
State	Published - Dec 28 2024

Keywords

heliosphere
kinetic microinstabilities
magnetosheath
plasma instabilities
space plasma physics
turbulence

ASJC Scopus subject areas

Geophysics
General Earth and Planetary Sciences

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10.1029/2024GL112038

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title = "Turbulent Energy Conversion Associated With Kinetic Microinstabilities in Earth's Magnetosheath",

abstract = "Plasma in Earth's magnetosheath rarely experiences interparticle collisions, so kinetic microinstabilities are thought to contribute to regulating the plasma thermodynamics. Instabilities excite waves and redistribute free energy in velocity space, reducing free energy in the velocity distribution function (VDF). Using 24 hr of data spread over 163 intervals of in situ magnetosheath observations by Magnetospheric Multiscale (MMS), we investigate signatures of energy conversion where the turbulent dynamics have locally distorted the VDFs into non-Maxwellian shapes, in the context of electron and ion temperature anisotropy driven instabilities. We find enhanced average energy conversion into the particles along instability boundaries, suggesting turbulence plays a role in redistributing free energy. In so doing, we quantify the energetics associated with unstable conditions for both species. This work provides insight into the open question of how specific plasma processes couple into the turbulent dynamics, ultimately leading to energy dissipation and particle energization in collisionless plasmas.",

keywords = "heliosphere, kinetic microinstabilities, magnetosheath, plasma instabilities, space plasma physics, turbulence",

author = "Lewis, {Harry C.} and Stawarz, {Julia E.} and Lorenzo Matteini and Luca Franci and Klein, {Kristopher G.} and Wicks, {Robert T.} and Salem, {Chadi S.} and Horbury, {Timothy S.} and Wang, {Joseph H.}",

note = "Publisher Copyright: {\textcopyright} 2024. The Author(s).",

year = "2024",

month = dec,

day = "28",

doi = "10.1029/2024GL112038",

language = "English (US)",

volume = "51",

journal = "Geophysical Research Letters",

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T1 - Turbulent Energy Conversion Associated With Kinetic Microinstabilities in Earth's Magnetosheath

AU - Lewis, Harry C.

AU - Stawarz, Julia E.

AU - Matteini, Lorenzo

AU - Franci, Luca

AU - Klein, Kristopher G.

AU - Wicks, Robert T.

AU - Salem, Chadi S.

AU - Horbury, Timothy S.

AU - Wang, Joseph H.

PY - 2024/12/28

Y1 - 2024/12/28

N2 - Plasma in Earth's magnetosheath rarely experiences interparticle collisions, so kinetic microinstabilities are thought to contribute to regulating the plasma thermodynamics. Instabilities excite waves and redistribute free energy in velocity space, reducing free energy in the velocity distribution function (VDF). Using 24 hr of data spread over 163 intervals of in situ magnetosheath observations by Magnetospheric Multiscale (MMS), we investigate signatures of energy conversion where the turbulent dynamics have locally distorted the VDFs into non-Maxwellian shapes, in the context of electron and ion temperature anisotropy driven instabilities. We find enhanced average energy conversion into the particles along instability boundaries, suggesting turbulence plays a role in redistributing free energy. In so doing, we quantify the energetics associated with unstable conditions for both species. This work provides insight into the open question of how specific plasma processes couple into the turbulent dynamics, ultimately leading to energy dissipation and particle energization in collisionless plasmas.

AB - Plasma in Earth's magnetosheath rarely experiences interparticle collisions, so kinetic microinstabilities are thought to contribute to regulating the plasma thermodynamics. Instabilities excite waves and redistribute free energy in velocity space, reducing free energy in the velocity distribution function (VDF). Using 24 hr of data spread over 163 intervals of in situ magnetosheath observations by Magnetospheric Multiscale (MMS), we investigate signatures of energy conversion where the turbulent dynamics have locally distorted the VDFs into non-Maxwellian shapes, in the context of electron and ion temperature anisotropy driven instabilities. We find enhanced average energy conversion into the particles along instability boundaries, suggesting turbulence plays a role in redistributing free energy. In so doing, we quantify the energetics associated with unstable conditions for both species. This work provides insight into the open question of how specific plasma processes couple into the turbulent dynamics, ultimately leading to energy dissipation and particle energization in collisionless plasmas.

KW - heliosphere

KW - kinetic microinstabilities

KW - magnetosheath

KW - plasma instabilities

KW - space plasma physics

KW - turbulence

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DO - 10.1029/2024GL112038

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VL - 51

JO - Geophysical Research Letters

JF - Geophysical Research Letters

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ER -

Turbulent Energy Conversion Associated With Kinetic Microinstabilities in Earth's Magnetosheath

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Keywords

ASJC Scopus subject areas

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