A Gyrokinetik Vlasov code for the study of the charge separation at a plasma edge

Wolfgang Entler; Gerald Kamelander; M. Shoucri

A Gyrokinetik Vlasov code for the study of the charge separation at a plasma edge

Wolfgang Entler, Gerald Kamelander, M. Shoucri

Radiation, Safety and Applications

Publikation: Beitrag in Buch oder Tagungsband › Vortrag mit Beitrag in Tagungsband › Begutachtung

Abstract

The existence and time evolution of a charge separation at a plasma edge is studied using a code in which both ions and electrons are described by three-dimensional (3D) gyro-kinetic equations that include the finite Larmor-radius correction and the polarization drift. The ions finite Larmor radius allows the existence of a charge separation between ions and electronics, and the polarization drift, which has opposite signs for ions and electrons, has a tendency to accentuate the charge separation in a time-varying electric field and in the presence of strong gradients. We present the results obtained for the case of a 3D layer, in which z represents the toroidal periodic direction, x represents the poloidal periodic direction and y represents the radial direction. The magnetic field is located in the x-z plane, very close to the toroidal direction z, and makes an angle 0= 89.5"o with the x-axis.

Originalsprache	Englisch
Titel	17th International Conference on the Numerical Simulkation of Plasmas
Seiten	105-109
Seitenumfang	5
Publikationsstatus	Veröffentlicht - 2000
Veranstaltung	17th International Conference on the Numerical Simulkation of Plasmas - Dauer: 1 Jan. 2000 → …

Konferenz

Konferenz	17th International Conference on the Numerical Simulkation of Plasmas
Zeitraum	1/01/00 → …

Research Field

Biosensor Technologies

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@inproceedings{5565fe538ce743a0b863a421b8f6d67f,

title = "A Gyrokinetik Vlasov code for the study of the charge separation at a plasma edge",

abstract = "The existence and time evolution of a charge separation at a plasma edge is studied using a code in which both ions and electrons are described by three-dimensional (3D) gyro-kinetic equations that include the finite Larmor-radius correction and the polarization drift. The ions finite Larmor radius allows the existence of a charge separation between ions and electronics, and the polarization drift, which has opposite signs for ions and electrons, has a tendency to accentuate the charge separation in a time-varying electric field and in the presence of strong gradients. We present the results obtained for the case of a 3D layer, in which z represents the toroidal periodic direction, x represents the poloidal periodic direction and y represents the radial direction. The magnetic field is located in the x-z plane, very close to the toroidal direction z, and makes an angle 0= 89.5{"}o with the x-axis.",

author = "Wolfgang Entler and Gerald Kamelander and M. Shoucri",

year = "2000",

language = "English",

pages = "105--109",

booktitle = "17th International Conference on the Numerical Simulkation of Plasmas",

note = "17th International Conference on the Numerical Simulkation of Plasmas ; Conference date: 01-01-2000",

}

TY - GEN

T1 - A Gyrokinetik Vlasov code for the study of the charge separation at a plasma edge

AU - Entler, Wolfgang

AU - Kamelander, Gerald

AU - Shoucri, M.

PY - 2000

Y1 - 2000

N2 - The existence and time evolution of a charge separation at a plasma edge is studied using a code in which both ions and electrons are described by three-dimensional (3D) gyro-kinetic equations that include the finite Larmor-radius correction and the polarization drift. The ions finite Larmor radius allows the existence of a charge separation between ions and electronics, and the polarization drift, which has opposite signs for ions and electrons, has a tendency to accentuate the charge separation in a time-varying electric field and in the presence of strong gradients. We present the results obtained for the case of a 3D layer, in which z represents the toroidal periodic direction, x represents the poloidal periodic direction and y represents the radial direction. The magnetic field is located in the x-z plane, very close to the toroidal direction z, and makes an angle 0= 89.5"o with the x-axis.

AB - The existence and time evolution of a charge separation at a plasma edge is studied using a code in which both ions and electrons are described by three-dimensional (3D) gyro-kinetic equations that include the finite Larmor-radius correction and the polarization drift. The ions finite Larmor radius allows the existence of a charge separation between ions and electronics, and the polarization drift, which has opposite signs for ions and electrons, has a tendency to accentuate the charge separation in a time-varying electric field and in the presence of strong gradients. We present the results obtained for the case of a 3D layer, in which z represents the toroidal periodic direction, x represents the poloidal periodic direction and y represents the radial direction. The magnetic field is located in the x-z plane, very close to the toroidal direction z, and makes an angle 0= 89.5"o with the x-axis.

M3 - Conference Proceedings with Oral Presentation

SP - 105

EP - 109

BT - 17th International Conference on the Numerical Simulkation of Plasmas

T2 - 17th International Conference on the Numerical Simulkation of Plasmas

Y2 - 1 January 2000

ER -

A Gyrokinetik Vlasov code for the study of the charge separation at a plasma edge

Abstract

Konferenz

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