Asymptotic stability of equilibrium states for ambipolar plasmas

V. Giovangigli; B. Graille

doi:10.1142/S0218202504003659

Asymptotic stability of equilibrium states for ambipolar plasmas

V. Giovangigli
, B. Graille

Ecole polytechnique

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

Abstract

We investigate a system of partial differential equations modeling ambipolar plasmas. The ambipolar - or zero current - model is obtained from general plasmas equations in the limit of vanishing Debye length. In this model, the electric field is expressed as a linear combination of macroscopic variable gradients. We establish that the governing equations can be written as a symmetric form by using entropic variables. The corresponding dissipation matrices satisfy the null space invariant property and the system of partial differential equations can be written as a normal form, i.e. in the form of a symmetric hyperbolic-parabolic composite system. By properly modifying the chemistry source terms and/or the diffusion matrices, asymptotic stability of equilibrium states is established and decay estimates are obtained. We also establish the continuous dependence of global solutions with respect to vanishing electron mass.

Original language	English
Pages (from-to)	1361-1399
Number of pages	39
Journal	Mathematical Models and Methods in Applied Sciences
Volume	14
Issue number	9
DOIs	https://doi.org/10.1142/S0218202504003659
Publication status	Published - 1 Sept 2004

Keywords

Ambipolar plasmas
Asymptotic stability
Chemical reactions
Equilibrium states
Ionized gas mixtures
Normal forms
Plasmas
Symmetric hyperbolic/parabolic system

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title = "Asymptotic stability of equilibrium states for ambipolar plasmas",

abstract = "We investigate a system of partial differential equations modeling ambipolar plasmas. The ambipolar - or zero current - model is obtained from general plasmas equations in the limit of vanishing Debye length. In this model, the electric field is expressed as a linear combination of macroscopic variable gradients. We establish that the governing equations can be written as a symmetric form by using entropic variables. The corresponding dissipation matrices satisfy the null space invariant property and the system of partial differential equations can be written as a normal form, i.e. in the form of a symmetric hyperbolic-parabolic composite system. By properly modifying the chemistry source terms and/or the diffusion matrices, asymptotic stability of equilibrium states is established and decay estimates are obtained. We also establish the continuous dependence of global solutions with respect to vanishing electron mass.",

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TY - JOUR

T1 - Asymptotic stability of equilibrium states for ambipolar plasmas

AU - Giovangigli, V.

AU - Graille, B.

PY - 2004/9/1

Y1 - 2004/9/1

N2 - We investigate a system of partial differential equations modeling ambipolar plasmas. The ambipolar - or zero current - model is obtained from general plasmas equations in the limit of vanishing Debye length. In this model, the electric field is expressed as a linear combination of macroscopic variable gradients. We establish that the governing equations can be written as a symmetric form by using entropic variables. The corresponding dissipation matrices satisfy the null space invariant property and the system of partial differential equations can be written as a normal form, i.e. in the form of a symmetric hyperbolic-parabolic composite system. By properly modifying the chemistry source terms and/or the diffusion matrices, asymptotic stability of equilibrium states is established and decay estimates are obtained. We also establish the continuous dependence of global solutions with respect to vanishing electron mass.

AB - We investigate a system of partial differential equations modeling ambipolar plasmas. The ambipolar - or zero current - model is obtained from general plasmas equations in the limit of vanishing Debye length. In this model, the electric field is expressed as a linear combination of macroscopic variable gradients. We establish that the governing equations can be written as a symmetric form by using entropic variables. The corresponding dissipation matrices satisfy the null space invariant property and the system of partial differential equations can be written as a normal form, i.e. in the form of a symmetric hyperbolic-parabolic composite system. By properly modifying the chemistry source terms and/or the diffusion matrices, asymptotic stability of equilibrium states is established and decay estimates are obtained. We also establish the continuous dependence of global solutions with respect to vanishing electron mass.

KW - Ambipolar plasmas

KW - Asymptotic stability

KW - Chemical reactions

KW - Equilibrium states

KW - Ionized gas mixtures

KW - Normal forms

KW - Plasmas

KW - Symmetric hyperbolic/parabolic system

U2 - 10.1142/S0218202504003659

DO - 10.1142/S0218202504003659

M3 - Article

AN - SCOPUS:7244239012

SN - 0218-2025

VL - 14

SP - 1361

EP - 1399

JO - Mathematical Models and Methods in Applied Sciences

JF - Mathematical Models and Methods in Applied Sciences

IS - 9

ER -

Asymptotic stability of equilibrium states for ambipolar plasmas

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Keywords

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