Characterisation of electron cyclotron wall conditioning plasma in ASDEX Upgrade

Wauters, T.; Buermans, J.; Cavalier, Jordan; Huett, E.; Ragona, R.; Svoboda, Jakub; Bobkov, V.; Griener, M.; Jacobsen, A. S.; Kallenbach, A.; Likonen, J.; Loarer, T.; Lunt, T.; Nielsen, S.K.; Pitts, R.A.; Ricci, D.; Rohde, V.; Stober, J.; Schneider, P.; Usoltseva, M.

doi:https://dx.doi.org/10.1088/1741-4326/acc674

Number of the records: 1

Characterisation of electron cyclotron wall conditioning plasma in ASDEX Upgrade

1.

SYSNO ASEP	0572767
Document Type	J - Journal Article
R&D Document Type	Journal Article
Subsidiary J	Článek ve WOS
Title	Characterisation of electron cyclotron wall conditioning plasma in ASDEX Upgrade
Author(s)	Wauters, T. (FR) Buermans, J. (BE) Cavalier, Jordan (UFP-V)_{RID, ORCID} Huett, E. (CH) Ragona, R. (DK) Svoboda, Jakub (UFP-V) Bobkov, V. (DE) Griener, M. (DE) Jacobsen, A. S. (DK) Kallenbach, A. (DE) Likonen, J. (FI) Loarer, T. (FR) Lunt, T. (DE) Nielsen, S.K. (DK) Pitts, R.A. (FR) Ricci, D. (IT) Rohde, V. (DE) Stober, J. (DE) Schneider, P. (DE) Usoltseva, M. (RU)
Number of authors	20
Article number	066018
Source Title	Nuclear Fusion. - : Institute of Physics Publishing - ISSN 0029-5515 Roč. 63, č. 6 (2023)
Number of pages	11 s.
Language	eng - English
Country	US - United States
Keywords	ecrh ; ecwc ; iter ; wall conditioning
Subject RIV	BL - Plasma and Gas Discharge Physics
OECD category	Fluids and plasma physics (including surface physics)
R&D Projects	9D22001 GA MŠMT - Ministry of Education, Youth and Sports (MEYS)
Method of publishing	Open access
Institutional support	UFP-V - RVO:61389021
UT WOS	000970782800001
EID SCOPUS	85152926922
DOI	10.1088/1741-4326/acc674
Annotation	Electron cyclotron wall condition (ECWC) discharges are characterised in ASDEX Upgrade with full tungsten plasma facing components and X2 polarised waves launched from the equatorial ports, relevant to ECWC conditions in ITER Pre-Fusion Power Operation phase 1. The characterisation of the deuterium plasmas is based on experimental inputs such as electron density measurements, in-vessel pressure measurements, poloidal field maps obtained from the measured coil currents, as well as advanced tomographic methods on camera images filtered at the hydrogen Balmer lines. TOMATOR-1D simulations and collective Thomson scattering radiometer spectra complement the findings. The cold, high density and partially ionized toroidal plasmas show significant levels of stray radiation. The measured radiation includes waves at half of the gyrotron frequency suggesting the occurrence of parametric decay instabilities at 2nd harmonic upper hybrid resonance that locates at the low field side of the resonance. A displacement of the plasma emission along the resonance layer is observed at higher discharge power in discharges with a vertical poloidal magnetic field only. By optimizing the poloidal field pattern, along with the location of the electron cyclotron heating (ECH) resonance, the strongest surface interaction regions for the charged particles can be controlled. Directing plasma flux to inner wall surfaces, and same for the inner divertor apron, is found less effective in ASDEX Upgrade due to magnetic mirror effects and outward convective flows. Modeling however predicts the presence of an intense and uniform flux of low energy atoms produced at the ECH absorption layer that may be effective for conditioning the high field side surfaces after use of the disruption mitigation system.
Workplace	Institute of Plasma Physics
Contact	Vladimíra Kebza, kebza@ipp.cas.cz, Tel.: 266 052 975
Year of Publishing	2024
Electronic address	https://iopscience.iop.org/article/10.1088/1741-4326/acc674

Number of the records: 1