During the initial operation of the International Thermonuclear Experimental Reactor (ITER), it is envisaged that
activation will be minimized by using hydrogen (H) plasmas where the reference ion cyclotron resonance frequency
(ICRF) heating scenarios rely on minority species such as helium (3He) or deuterium (D). This paper firstly describes
experiments dedicated to the study of 3He heating in H plasmas with a sequence of discharges in which 5MW of
ICRF power was reliably coupled and the 3He concentration, controlled in real-time, was varied from below 1% up
to 10%. The minority heating (MH) regimewas observed at lowconcentrations (up to 2%). Energetic tails in the 3He
ion distributions were observed with effective temperatures up to 300 keVand bulk electron temperatures up to 6 keV.
At around 2%, a sudden transition was reproducibly observed to the mode conversion regime, in which the ICRF fast
wave couples to short wavelength modes, leading to efficient direct electron heating and bulk electron temperatures
up to 8 keV. Secondly, experiments performed to study D minority ion heating in H plasmas are presented. This
MH scheme proved much more difficult since modest quantities of carbon (C) impurity ions, which have the same
charge to mass ratio as the D ions, led directly to the mode conversion regime. Finally, numerical simulations to
interpret these two sets of experiments are under way and preliminary results are shown.
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