Kinetic theory of plasma waves - Part I: introduction

P. U. Lamalle

doi:10.13182/fst00-a11963205

Kinetic theory of plasma waves - Part I: introduction

P. U. Lamalle

Laboratory for Plasma Physics

EFDA-JET

Publikation: Beitrag in Fachzeitschrift › Konferenzartikel › Begutachtung

Abstract

The kinetic description of linear waves in plasmas is succinctly presented, with emphasis on applications to high-frequency (hf) wave heating and current drive. The Maxwell-Vlasov system of equations is introduced. Its two-timescale analysis yields the linearized Vlasov and the quasilinear Fokker-Planck equations. The standard guiding centre and Hamiltonian formalisms are presented. Two formulations of the hf plasma wave equation are given: as a partial differential equation to hold at each position, and as a global Galerkin ('variational') form.

Originalsprache	Englisch
Seiten (von - bis)	112-117
Seitenumfang	6
Fachzeitschrift	Fusion Technology
Jahrgang	37
Ausgabenummer	2 T
DOIs	https://doi.org/10.13182/fst00-a11963205
Publikationsstatus	Veröffentlicht - März 2000
Veranstaltung	4th Carolus Magnus Summer School on Plasma Physics - Maastricht, Niederlande Dauer: 30 Aug. 1999 → 10 Sept. 1999

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10.13182/fst00-a11963205

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title = "Kinetic theory of plasma waves - Part I: introduction",

abstract = "The kinetic description of linear waves in plasmas is succinctly presented, with emphasis on applications to high-frequency (hf) wave heating and current drive. The Maxwell-Vlasov system of equations is introduced. Its two-timescale analysis yields the linearized Vlasov and the quasilinear Fokker-Planck equations. The standard guiding centre and Hamiltonian formalisms are presented. Two formulations of the hf plasma wave equation are given: as a partial differential equation to hold at each position, and as a global Galerkin ('variational') form.",

author = "Lamalle, \{P. U.\}",

year = "2000",

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doi = "10.13182/fst00-a11963205",

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N2 - The kinetic description of linear waves in plasmas is succinctly presented, with emphasis on applications to high-frequency (hf) wave heating and current drive. The Maxwell-Vlasov system of equations is introduced. Its two-timescale analysis yields the linearized Vlasov and the quasilinear Fokker-Planck equations. The standard guiding centre and Hamiltonian formalisms are presented. Two formulations of the hf plasma wave equation are given: as a partial differential equation to hold at each position, and as a global Galerkin ('variational') form.

AB - The kinetic description of linear waves in plasmas is succinctly presented, with emphasis on applications to high-frequency (hf) wave heating and current drive. The Maxwell-Vlasov system of equations is introduced. Its two-timescale analysis yields the linearized Vlasov and the quasilinear Fokker-Planck equations. The standard guiding centre and Hamiltonian formalisms are presented. Two formulations of the hf plasma wave equation are given: as a partial differential equation to hold at each position, and as a global Galerkin ('variational') form.

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AN - SCOPUS:0034158972

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JO - Fusion Technology

JF - Fusion Technology

IS - 2 T

Y2 - 30 August 1999 through 10 September 1999

ER -

Kinetic theory of plasma waves - Part I: introduction

Abstract

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