Wave modelling in a cylindrical non-uniform helicon discharge
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Date
Authors
Chang, L.
Hole, M. J.
Caneses, J. F.
Chen, G.
Blackwell, B. D.
Corr, C. S.
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American Institute of Physics (AIP)
Abstract
A radio frequency (RF) field solver based on Maxwell's equations and a cold
plasma dielectric tensor is em- ployed to describe wave phenomena observed in a
cylindrical non-uniform helicon discharge. The experiment is carried out on a
recently built linear plasma-material interaction machine: the MAGnetized
Plasma In- teraction Experiment (MAGPIE) [B. D. Blackwell, J. F. Caneses, C.
Samuell, J. Wach, J. Howard, and C. S. Corr, submitted on 25 March 2012 to
Plasma Sources Science and Technology], in which both plasma density and static
magnetic field are functions of axial position. The field strength increases by
a factor of 15 from source to target plate, and plasma density and electron
temperature are radially non-uniform. With an enhancement factor of 9.5 to the
electron-ion Coulomb collision frequency, 12% reduction in the antenna radius,
and the same other conditions as employed in the experiment, the solver
produces axial and radial profiles of wave amplitude and phase that are
consistent with measurements. Ion-acoustic turbulence, which can happen if
electron drift velocity exceeds the speed of sound in magnetized plasmas, may
account for the factor of 9.5 used to match simulated results with experimental
data. To overcome the single m vacuum solu- tion limitations of the RF solver,
which can only compute the glass response to the same mode number of the
antenna, we have adjusted the antenna radius to match the wave field strength
in the plasma.(not finished because of the limited number of characters, please
see the full paper)
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Physics of Plasmas
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