ICRH operations and experiments during the JET-ILW tritium and DTE2 campaigns

P. Jacquet, E. Lerche, M. Mantsinen, D. Van Eester, K. Kirov, P. Mantica, D. Gallart, D. Taylor, Y. Kazakov, I. Monakhov, C. Noble, P. Dumortier, H. Sheikh, C. Challis, J. Hobirk, A. Kappatou, M. Maslov, D. King, D. Keeling, F. RiminiD. Frigione, L. Garzotti, P. Lomas, C. Lowry, I. Carvalho, M. Baruzzo, C. Reux, M. Lenholm, R. Henriques, E. De La Luna, J. Mailloux, C. Maggi, J. Garcia, A. Chomiczewska, W. Gromelski, V. Bobkov, D. Milanesio, L. Colas, W. Tierens, R. Otin, C. Klepper, E. Delabie, R. Dumont, J. Eriksson, V. Kiptily, S. Menmuir, M. Nocente, A. Patel, G. Pucella, D. Rigamonti, M. Tardochi, S. Silburn, P. Siren, E. Solano, Z. Stancar, M. Valisa, D. Douai, D. Matveev, T. Wauters

Research output: Contribution to journalConference articlepeer-review

6 Scopus citations

Abstract

2021 has culminated with the completion of the JET-ILW DTE2 experimental campaign. This contribution summarizes Ion Cyclotron Resonance Heating (ICRH) operations from system and physics point of view. Improvements to the (ICRH) system, to operation procedures and to real time RF power control were implemented to address specific constraints from tritium and deuterium-tritium operations and increase the system reliability and power availability during D-T pulses. ICRH was operated without the ITER-Like Antenna (ILA) because water leaked from an in-vessel capacitor into the vessel on day-2 of the D-T campaign. Three weeks were required to identify and isolate the leak and resume plasma operations. Dedicated RF-Plasma Wall Interaction (PWI) experiments were conducted; tritium plasmas exhibit a higher level of Be sputtering on the outer wall and impurity content when compared to deuterium or hydrogen plasmas. The JET-DTE2 campaigns provided the opportunity to characterize ICRH schemes foreseen for the ITER operation, in the ITER like wall environment in ELMy H-mode scenarios aiming at maximizing fusion performance. The second harmonic tritium resonance heating and to a lesser extent minority 3He heating (ITER D-T ICRH reference schemes) lead to improved ion temperature and fusion performance when compared to hydrogen minority ICRH. However, these discharges suffered from a lack of stationarity and gradual impurity accumulation potentially because of a deficit of ICRH power when using JET antennas at lower frequencies. Fundamental deuterium ICRH was used in tritium-rich plasmas and with deuterium Neutral Beam Heating; this ICRH scheme proved to be very efficient boosting ion temperature and fusion performance in these plasmas.

Original languageEnglish
Article number030003
JournalAIP Conference Proceedings
Volume2984
Issue number1
DOIs
StatePublished - Aug 18 2023
Event24th Topical Conference on Radio-frequency Power in Plasmas - Annapolis, United States
Duration: Sep 26 2022Sep 28 2022

Funding

See the author list of J. Mailloux et al., Nuclear Fusion 62, 042026 (2022) for the list of JET Contributors. This work has been carried out within the framework of the EUROfusion Consortium, funded by the European Union via the Euratom Research and Training Programme (Grant Agreement No 101052200 - EUROfusion) and from the EPSRC (grant number EP/W006839/1). Some part of this work has also been carried out within the framework of the Contract for the Operation of the JET Facilities and has received funding from the European Union’s Horizon 2020 research and innovation programme. Views and opinions expressed are however those of the author(s) only and do not necessarily reflect those of the European Union or the European Commission. Neither the European Union nor the European Commission can be held responsible for them.

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