TY - GEN
T1 - Monte Carlo simulation of initial breakdown phase for magnetised toroidal ICRF discharges
AU - Tripský, M.
AU - Wauters, T.
AU - Lyssoivan, A.
AU - Koch, R.
AU - Bobkov, V.
AU - Vervier, M.
AU - Van Oost, G.
AU - Van Schoor, M.
PY - 2014
Y1 - 2014
N2 - The radio-frequency (RF) plasma production technique in the ion cyclotron range of frequency (ICRF) attracts growing attention among fusion experts because of its high potential for solving several basic problems of reactor-oriented superconducting fusion machines, such as ICRF wall conditioning in tokamaks and stellarators (Te=3-5eV, ne<1012cm -3), ICRF-assisted tokamak start-up and target plasma production (ne=1013cm-3) in stellarators. Plasma initiation by ICRF has been studied intensively using single particle descriptions and basic analytic models. To further improve the present understanding on plasma production employing the vacuum RF field of ICRF antennas in toroidal devices in presence of the toroidal magnetic field, and its parametric dependencies a Monte Carlo code has been developed. The 1D code RFdinity1D describes the motion of electrons, accelerated by the RF field in front of the ICRF antenna, along one toroidal magnetic field line. Dependent on their individual energies and the related electron collision cross sections (ionisation, excitation and dissociation) weighted by a Monte Carlo procedure, an electron avalanche may occur. Breakdown conditions are discussed as function of RF discharge parameters (i) RF vacuum electric field strength, (ii) RF frequency and (iii) neutral pressure (H2). The slope of the exponential density increase, taken as measure for the breakdown speed, shows qualitative agreement to experimental breakdown times as found in literature and experimental data of the ASDEX upgrade and TEXTOR tokamak, and is interpreted by studying the characteristic electron velocity distribution functions.
AB - The radio-frequency (RF) plasma production technique in the ion cyclotron range of frequency (ICRF) attracts growing attention among fusion experts because of its high potential for solving several basic problems of reactor-oriented superconducting fusion machines, such as ICRF wall conditioning in tokamaks and stellarators (Te=3-5eV, ne<1012cm -3), ICRF-assisted tokamak start-up and target plasma production (ne=1013cm-3) in stellarators. Plasma initiation by ICRF has been studied intensively using single particle descriptions and basic analytic models. To further improve the present understanding on plasma production employing the vacuum RF field of ICRF antennas in toroidal devices in presence of the toroidal magnetic field, and its parametric dependencies a Monte Carlo code has been developed. The 1D code RFdinity1D describes the motion of electrons, accelerated by the RF field in front of the ICRF antenna, along one toroidal magnetic field line. Dependent on their individual energies and the related electron collision cross sections (ionisation, excitation and dissociation) weighted by a Monte Carlo procedure, an electron avalanche may occur. Breakdown conditions are discussed as function of RF discharge parameters (i) RF vacuum electric field strength, (ii) RF frequency and (iii) neutral pressure (H2). The slope of the exponential density increase, taken as measure for the breakdown speed, shows qualitative agreement to experimental breakdown times as found in literature and experimental data of the ASDEX upgrade and TEXTOR tokamak, and is interpreted by studying the characteristic electron velocity distribution functions.
KW - ICRF
KW - Monte Carlo
KW - RF discharge production
KW - Tokamak
UR - http://www.scopus.com/inward/record.url?scp=84906351120&partnerID=8YFLogxK
U2 - 10.1063/1.4864556
DO - 10.1063/1.4864556
M3 - Conference contribution
AN - SCOPUS:84906351120
SN - 9780735412101
T3 - AIP Conference Proceedings
SP - 334
EP - 337
BT - Radiofrequency Power in Plasmas - Proceedings of the 20th Topical Conference
PB - American Institute of Physics Inc.
T2 - 20th Topical Conference on Radiofrequency Power in Plasmas
Y2 - 25 June 2013 through 28 June 2013
ER -