Fundamental ion cyclotron resonance heating of JET deuterium plasmas

Krasilnikov, A V; Van Eester, D; Lerche, E; Ongena, J; Amosov, V N; Biewer, Theodore M; Bonheure, G; Crombe, K; Ericsson, G; Esposito, Basilio; Giacomelli, L; Hellesen, C; Hjalmarsson, A; Jachmich, S; Kallne, J; Kaschuck, Yu A; Kiptily, V; Leggate, H; Mailloux, J; Marocco, D; Mayoral, M -L; Popovichev, S; Riva, M; Santala, M; Stamp, M F; Vdovin, V; Walden, A

doi:10.1088/0741-3335/51/4/044005

Title: Fundamental ion cyclotron resonance heating of JET deuterium plasmas

Journal Article · Sun Mar 01 00:00:00 EST 2009 · Plasma Physics and Controlled Fusion

DOI:https://doi.org/10.1088/0741-3335/51/4/044005· OSTI ID:1000722

Krasilnikov, A V ^[1]; Van Eester, D ^[2]; Lerche, E ^[2]; Ongena, J ^[2]; Amosov, V N ^[1]; Biewer, Theodore M ^[3]; Bonheure, G ^[2]; Crombe, K ^[4]; Ericsson, G ^[5]; Esposito, Basilio ^[6]; Giacomelli, L ^[5]; Hellesen, C ^[5]; Hjalmarsson, A ^[5]; Jachmich, S ^[7]; Kallne, J ^[5]; Kaschuck, Yu A ^[1]; Kiptily, V ^[7]; Leggate, H ^[7]; Mailloux, J ^[7]; Marocco, D ^[6] more »

Troitsk Institute of Nuclear Physics (TRINITI), Russia
Laboratory for Plasma Physics-ERM/KMS (LPP-ERM/KMS), Brussels, Belgium
ORNL
Ghent University, Belgium
Uppsala University, Uppsala, Sweden
ENEA, Frascati
EURATOM / UKAEA, UK
Russian Research Center, Kurchatov Institute, Moscow, Russia

Radio frequency heating of majority ions is of prime importance for understanding the basic role of auxiliary heating in the activated D T phase of ITER. Majority deuterium ion cyclotron resonance heating (ICRH) experiments at the fundamental cyclotron frequency were performed in JET. In spite of the poor antenna coupling at 25 MHz, this heating scheme proved promising when adopted in combination with D neutral beam injection (NBI). The effect of fundamental ICRH of a D population was clearly demonstrated in these experiments: by adding ~25% of heating power the fusion power was increased up to 30 50%, depending on the type of NBI adopted. At this power level, the ion and electron temperatures increased from Ti ~ 4.0 keV and Te ~ 4.5 keV (NBI-only phase) to Ti ~ 5.5 keV and Te ~ 5.2 keV (ICRH + NBI phase), respectively. The increase in the neutron yield was stronger when 80 keV rather than 130 keV deuterons were injected in the plasma. It is shown that the neutron rate, the diamagnetic energy and the electron as well as the ion temperature scale roughly linearly with the applied RF power. A synergistic effect of the combined use of ICRF and NBI heating was observed: (i) the number of neutron counts measured by the neutron camera during the combined ICRF + NBI phases of the discharges exceeded the sum of the individual counts of the NBI-only and ICRF-only phases; (ii) a substantial increase in the number of slowing-down beam ions was detected by the time of flight neutron spectrometer when ICRF power was switched on; (iii) a small D subpopulation with energies slightly above the NBI launch energy was detected by the neutral particle analyzer and -ray spectroscopy.

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Research Organization:: Oak Ridge National Lab. (ORNL), Oak Ridge, TN (United States)

Sponsoring Organization:: USDOE Office of Science (SC)

DOE Contract Number:: DE-AC05-00OR22725

OSTI ID:: 1000722

Journal Information:: Plasma Physics and Controlled Fusion, Vol. 51, Issue 4; ISSN 0741--3335

Country of Publication:: United States

Language:: English

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