Authors: N. Bertelli, E. J. Valeo, M.
Gorelenkova, C. K. Phillips, M. Podest'a
Abstract: At the power levels required for
significant heating and current drive in magnetically-confined
toroidal plasma, modification of the particle distribution
function from a Maxwellian shape is likely [T. H. Stix, Nucl.
Fusion, 15:737 1975], with consequent changes in wave
propagation and in the location and amount of absorption. In order
to study these effects computationally, both the
finite-Larmor-radius and the high-harmonic fast wave (HHFW),
full-wave, hot-plasma toroidal simulation code, TORIC [M.
Brambilla, Plasma Phys. Control. Fusion 41, 1 (1999) and M.
Brambilla, Plasma Phys. Control. Fusion 44, 2423 (2002)], have
been extended to allow the prescription of arbitrary velocity
distributions of the form (see attachment for formula).
For hydrogen (H) minority heating of a deuterium (D) plasma with
anisotropic Maxwellian H distributions, the fractional H
absorption varies significantly with changes in parallel
temperature but is essentially independent of perpendicular
temperature. On the other hand, for HHFW regime with anisotropic
Maxwellian fast ion distribution, the fractional beam ion
absorption varies mainly with changes in the perpendicular
temperature. The evaluation of the wave-field and power
absorption, through the full wave solver, with the ion
distribution function provided by either a Monte-Carlo particle
and Fokker-Planck codes is also examined for Alcator C-Mod and
NSTX plasmas. Non-Maxwellian effects generally tends to increase
the absorption with respect to the equivalent Maxwellian
distribution.
Submitted to: Nuclear Fusion
_________________________________________________________________________________________________
Download PPPL-5335 1.8
MB (pdf 17 pp)
_________________________________________________________________________________________________