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Influence of strong self-electric fields on the ion resonance instability in a nonneutral plasma column

Journal Article · · Phys. Fluids; (United States)
DOI:https://doi.org/10.1063/1.861813· OSTI ID:7209544
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The influence of strong self-electric fields on the ion resonance instability is examined for a cylindrical nonneutral plasma column immersed in a uniform axial magnetic field B/sub 0/e/sub z/. The analysis is carried out within the framework of a macroscopic cold-fluid model, and electrostatic stability properties are investigated for the case of rectangular electron and ion density profiles. The parameter delta= (2..omega../sup 2//sub p e//..omega../sup 2//sub c e/) (1-f) is introduced as a convenient measure of the relative strengths of the equilibrium self-electric force and the magnetic force on an electron fluid element. (Here, omega-circumflex/sub p e/ is the electron plasma frequency, ..omega../sub c e/ is the electron cyclotron frequency, f=n/sup 0//sub i//n/sup 0//sub e/ is the fractional charge neutralization, and delta=1 corresponds to the maximum allowed charge density for radial confinement of the equilibrium configuration.) An important conclusion of this study is that the equilibrium self-electric field can have a large influence on stability behavior. In particular, stability properties for delta9 or approx. =1 differ substantially from those obtained when deltavery-much-less-than1. Moreover, for nonneutral plasma column with significant charge neutralization, it is found that the fundamental mode (l=1) is not the most unstable mode. Rather, higher harmonic perturbations have larger growth rates. However, in the limiting case where fvery-much-less-than1 and deltavery-much-less-than1, the l=1 mode can have the largest growth rate, which is consistent with the result previously obtained by Levy, Daugherty, and Buneman.

Research Organization:
Division of Magnetic Fusion Energy, Energy Research and Development Administration, Washington, D. C. 20545
OSTI ID:
7209544
Journal Information:
Phys. Fluids; (United States), Journal Name: Phys. Fluids; (United States) Vol. 20:11; ISSN PFLDA
Country of Publication:
United States
Language:
English

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Related Subjects

70 PLASMA PHYSICS AND FUSION TECHNOLOGY
700107* -- Fusion Energy-- Plasma Research-- Instabilities
CONFIGURATION
CYLINDRICAL CONFIGURATION
DISPERSION RELATIONS
EIGENVALUES
ELECTRIC FIELDS
ELECTRON DENSITY
EQUILIBRIUM PLASMA
INSTABILITY
ION WAVE INSTABILITY
LANGMUIR FREQUENCY
MAGNETIC FIELD CONFIGURATIONS
PLASMA
PLASMA DENSITY
PLASMA INSTABILITY
PLASMA MICROINSTABILITIES