Kinetic study of instability growth rate in a helicon plasma discharge source

Kinetic study of instability growth rate in a helicon plasma discharge source

In this work, a kinetic model is developed to study the effects of the radio frequency antenna wavenumber, helicon plasma electron density, as well as their drift velocity and temperature on the instability increment rate of the helicon wave in both longitudinal and transverse directions. The ion ac...

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Bibliographic Details
Published in:Contributions to plasma physics (1988) Vol. 57; no. 6-7; pp. 272 - 281
Main Authors: Jaafarian, Rokhsare, Ganjovi, Alireza, Etaati, Gholam Reza
Format: Journal Article
Language:English
Published: Weinheim WILEY‐VCH Verlag GmbH & Co. KGaA 01-07-2017
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Subjects:
Antennas
Drift
Electron density
Electron energy
Growth rate
helicon plasma
instability increment rate
Metals
Permittivity
Plasma
Plasmas (physics)
Resonant frequencies
Stability
Temperature effects
Velocity
Wave energy
Wave power
Wavelengths
whistler waves
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Description
Summary:In this work, a kinetic model is developed to study the effects of the radio frequency antenna wavenumber, helicon plasma electron density, as well as their drift velocity and temperature on the instability increment rate of the helicon wave in both longitudinal and transverse directions. The ion acoustic (IA) wave frequencies and wavenumbers of the helicon waves are obtained when the maximum wave energy is deposited on the plasma ions. Moreover, it is shown that, at the IA wavenumber and frequencies, while the longitudinal instability increment rates for both the helicon and IA waves are ignorable, the transverse instability increment rate for both the helicon and IA wave increases. Besides, the longitudinal instability increment rate for the helicon or IA wave has non‐zero resonant frequencies. On the other hand, the transverse instability increment rate of helicon or IA wave can be neglected. Furthermore, it is observed that, while both the imaginary part of longitudinal permittivity and longitudinal instability increment rate are not influenced by the electron temperature, their transverse component increases linearly with the electron temperature. In addition, the imaginary part of transverse permittivity increases almost linearly with the drift velocity of the plasma electrons.
ISSN:0863-1042
1521-3986
DOI:10.1002/ctpp.201700041