Penetration of the rotating magnetic field into the plasma

D. W. Faulconer; R. Koch; Karl Finken

doi:10.1016/S0920-3796(97)00081-1

Penetration of the rotating magnetic field into the plasma

D. W. Faulconer
, R. Koch
, Karl Finken

Laboratory for Plasma Physics

FORSCHUNGSZENTRUM JULICH GMBH

Onderzoeksoutput: Bijdrage aan een tijdschrift › Artikel › peer review

18 Citaten (Scopus)

Samenvatting

The penetration of the dynamic ergodic divertor (DED) field into the plasma is described in the wave approximation over the projected frequency range, f≤ 10 kHz. Candidate waves are first described in the WKB sense, both cold-collisional and warm plasma approximations being employed. There follows an analysis in terms of the wave magnetic field which identifies the rotating DED field with the fast wave; a coupling calculation shows this wave to penetrate to the resonant surface as it would in vacuum, undiminished by the presence of plasma. Ideal MHD breaks down at the resonant surface, the resistive layer playing a dominant role.

Originele taal-2	Engels
Pagina's (van-tot)	399-409
Aantal pagina's	11
Tijdschrift	Fusion Engineering and Design
Volume	37
Nummer van het tijdschrift	3
DOI's	https://doi.org/10.1016/S0920-3796(97)00081-1
Status	Gepubliceerd - okt 1997

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title = "Penetration of the rotating magnetic field into the plasma",

abstract = "The penetration of the dynamic ergodic divertor (DED) field into the plasma is described in the wave approximation over the projected frequency range, f≤ 10 kHz. Candidate waves are first described in the WKB sense, both cold-collisional and warm plasma approximations being employed. There follows an analysis in terms of the wave magnetic field which identifies the rotating DED field with the fast wave; a coupling calculation shows this wave to penetrate to the resonant surface as it would in vacuum, undiminished by the presence of plasma. Ideal MHD breaks down at the resonant surface, the resistive layer playing a dominant role.",

keywords = "Cold collisional, Dynamic ergodic divertor, Resistive layer, Warm plasma approximations, Wave magnetic field",

author = "Faulconer, \{D. W.\} and R. Koch and Karl Finken",

year = "1997",

month = oct,

doi = "10.1016/S0920-3796(97)00081-1",

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AU - Faulconer, D. W.

AU - Koch, R.

AU - Finken, Karl

PY - 1997/10

Y1 - 1997/10

N2 - The penetration of the dynamic ergodic divertor (DED) field into the plasma is described in the wave approximation over the projected frequency range, f≤ 10 kHz. Candidate waves are first described in the WKB sense, both cold-collisional and warm plasma approximations being employed. There follows an analysis in terms of the wave magnetic field which identifies the rotating DED field with the fast wave; a coupling calculation shows this wave to penetrate to the resonant surface as it would in vacuum, undiminished by the presence of plasma. Ideal MHD breaks down at the resonant surface, the resistive layer playing a dominant role.

AB - The penetration of the dynamic ergodic divertor (DED) field into the plasma is described in the wave approximation over the projected frequency range, f≤ 10 kHz. Candidate waves are first described in the WKB sense, both cold-collisional and warm plasma approximations being employed. There follows an analysis in terms of the wave magnetic field which identifies the rotating DED field with the fast wave; a coupling calculation shows this wave to penetrate to the resonant surface as it would in vacuum, undiminished by the presence of plasma. Ideal MHD breaks down at the resonant surface, the resistive layer playing a dominant role.

KW - Cold collisional

KW - Dynamic ergodic divertor

KW - Resistive layer

KW - Warm plasma approximations

KW - Wave magnetic field

UR - https://www.scopus.com/pages/publications/0031248087

U2 - 10.1016/S0920-3796(97)00081-1

DO - 10.1016/S0920-3796(97)00081-1

M3 - Article

AN - SCOPUS:0031248087

SN - 0920-3796

VL - 37

SP - 399

EP - 409

JO - Fusion Engineering and Design

JF - Fusion Engineering and Design

IS - 3

ER -

Penetration of the rotating magnetic field into the plasma

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