Suitability of Moment Methods to Model the Ion Dynamics in a Low-Temperature Plasma

Anatole Berger; Nicolas Lequette; Thierry Magin; Anne Bourdon; Alejandro Alvarez Laguna

doi:10.1007/978-3-032-00094-1_34

Suitability of Moment Methods to Model the Ion Dynamics in a Low-Temperature Plasma

Anatole Berger
, Nicolas Lequette
, Thierry Magin
, Anne Bourdon
, Alejandro Alvarez Laguna

Sorbonne Université
Karman Institute for Fluid Dynamics

Research output: Chapter in Book/Report/Conference proceeding › Chapter › peer-review

Abstract

We present a study of the suitability of several moment methods to capture the ion dynamics in a bounded non-equilibrium low-temperature plasma between two electrically-floating walls under different pressure regimes. We use a set of kinetic simulations in order to study the properties of one-dimensional five-moment (1D 5M) closures. We discuss on the advantages and disadvantages of some of the most common moment methods: Grad’s closure, the quadrature method of moments (QMOM), the extended QMOM (EQMOM) and maximum entropy. For this study, we analyse the capability of each closure to capture the dynamics of the closing flux and its ability to retrieve the distribution function. The results show that the accuracy of each model largely depends on the pressure regime. In general, all the considered methods behave rather fine at high pressure and exhibit different challenges in order to represent the low-pressure regime.

Original language	English
Title of host publication	Springer Aerospace Technology
Publisher	Springer Science and Business Media Deutschland GmbH
Pages	357-367
Number of pages	11
DOIs	https://doi.org/10.1007/978-3-032-00094-1_34
Publication status	Published - 1 Jan 2026

Publication series

Name	Springer Aerospace Technology
Volume	Part F1507
ISSN (Print)	1869-1730
ISSN (Electronic)	1869-1749

Keywords

EQMOM
Grad
Ions
Maximum entropy
Moment methods
Particle-in-cell
Plasma discharge
QMOM

Access to Document

10.1007/978-3-032-00094-1_34

Cite this

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abstract = "We present a study of the suitability of several moment methods to capture the ion dynamics in a bounded non-equilibrium low-temperature plasma between two electrically-floating walls under different pressure regimes. We use a set of kinetic simulations in order to study the properties of one-dimensional five-moment (1D 5M) closures. We discuss on the advantages and disadvantages of some of the most common moment methods: Grad{\textquoteright}s closure, the quadrature method of moments (QMOM), the extended QMOM (EQMOM) and maximum entropy. For this study, we analyse the capability of each closure to capture the dynamics of the closing flux and its ability to retrieve the distribution function. The results show that the accuracy of each model largely depends on the pressure regime. In general, all the considered methods behave rather fine at high pressure and exhibit different challenges in order to represent the low-pressure regime.",

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Suitability of Moment Methods to Model the Ion Dynamics in a Low-Temperature Plasma. / Berger, Anatole; Lequette, Nicolas; Magin, Thierry et al.
Springer Aerospace Technology. Springer Science and Business Media Deutschland GmbH, 2026. p. 357-367 (Springer Aerospace Technology; Vol. Part F1507).

Research output: Chapter in Book/Report/Conference proceeding › Chapter › peer-review

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T1 - Suitability of Moment Methods to Model the Ion Dynamics in a Low-Temperature Plasma

AU - Berger, Anatole

AU - Lequette, Nicolas

AU - Magin, Thierry

AU - Bourdon, Anne

AU - Alvarez Laguna, Alejandro

N1 - Publisher Copyright: © The Author(s) 2026.

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AB - We present a study of the suitability of several moment methods to capture the ion dynamics in a bounded non-equilibrium low-temperature plasma between two electrically-floating walls under different pressure regimes. We use a set of kinetic simulations in order to study the properties of one-dimensional five-moment (1D 5M) closures. We discuss on the advantages and disadvantages of some of the most common moment methods: Grad’s closure, the quadrature method of moments (QMOM), the extended QMOM (EQMOM) and maximum entropy. For this study, we analyse the capability of each closure to capture the dynamics of the closing flux and its ability to retrieve the distribution function. The results show that the accuracy of each model largely depends on the pressure regime. In general, all the considered methods behave rather fine at high pressure and exhibit different challenges in order to represent the low-pressure regime.

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KW - Grad

KW - Ions

KW - Maximum entropy

KW - Moment methods

KW - Particle-in-cell

KW - Plasma discharge

KW - QMOM

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