Structure of the Bernstein modes for large values of the plasma parameter

R. W. Fredricks

doi:10.1017/S0022377800003755

Abstract

The electrostatic modes for which k is perpendicular to the impressed field B0 (the ‘Bernstein modes’) have been examined, and dispersion curves (w vs. k) have been calculated numerically for hybrid frequencies in the vicinity of the thirtieth to fortieth harmonic of the gyrofrequency. Although the calculations were performed for the lower hybrid case (ion branch), they also apply to the upper hybrid cases in which the plasma parameter The structure of the dispersion curves for these large values of plasma parameter differs from that for smaller values investigated by others, in that broad bands in wave-number space have very small group speeds in narrow frequency bands close to many of the gyrofrequency harmonics. All of the Bernstein modes examined have group speeds less than 37 % of the ion thermal speed, and can be classified as very slow waves. Furthermore, the spectrum of propagating Bernstein modes is broadened as becomes large, with an effective total transmission region from the gyrofrequency up to several harmonics of gyrofrequency above the hybrid frequency.

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Fredricks, R. W. 1968. Structure of generalized ion Bernstein modes from the full electromagnetic dispersion relation. Journal of Plasma Physics, Vol. 2, Issue. 3, p. 365.

Scarf, F. L. Crook, G. M. Green, I. M. and Virobik, P. F. 1968. Initial results of the Pioneer 8 VLF Electric Field Experiment. Journal of Geophysical Research, Vol. 73, Issue. 21, p. 6665.

Hirose, A. Alexeff, I. Jones, W.D. Krall, N.A. and Montgomery, D. 1969. Landau damping of electrostatic ion waves in a uniform magnetic field. Physics Letters A, Vol. 29, Issue. 1, p. 31.

Fejer, J. A. Axford, W. I. Banks, P. M. Brace, L. H. Calvert, W. Carpenter, D. L. Farley, D. T. Gurnett, D. A. Kennel, C. F. Liemohn, H. B. and Scarf, F. L. 1969. Commission 4: Progress in Magnetospheric Radio. Radio Science, Vol. 4, Issue. 7, p. 623.

Ueyanagi, Ki-ichi and Tanaka, Shigetoshi 1970. Dispersion of Electrostatic Ion Cyclotron Wave. Journal of the Physical Society of Japan, Vol. 28, Issue. 6, p. 1590.

Monfort, J.-L. and Vandenplas, P.E. 1970. Description of waves in a nonuniform magnetized plasma to all orders in electron and ion temperature. Physics Letters A, Vol. 31, Issue. 1, p. 11.

Hasti, D. E. Oakes, M. E. and Schlüter, H. 1970. Resistive loading by a finite plasma cylinder. Journal of Plasma Physics, Vol. 4, Issue. 4, p. 787.

Aubry, M. P. Bitoun, J. and Graff, Ph. 1970. Propagation and Group Velocity in a Warm Magnetoplasma. Radio Science, Vol. 5, Issue. 3, p. 635.

Buckley, R. 1971. Fluctuations in the interplanetary plasma. Planetary and Space Science, Vol. 19, Issue. 5, p. 421.

Ohnuma, T. Miyake, S. Sato, T. and Watari, T. 1971. Propagation of Electrostatic Ion Waves Near Ion Cyclotron Harmonics. Physical Review Letters, Vol. 26, Issue. 10, p. 541.

Beghin, C. and Debrie, R. 1972. Characteristics of the electric field far from and close to a radiating antenna around the lower hybrid resonance in the ionospheric plasma. Journal of Plasma Physics, Vol. 8, Issue. 3, p. 287.

Monfort, J.-L. and Vandenplas, P. E. 1972. Description to all orders in electron and ion temperatures of waves in magnetized nonuniform plasma. Transport Theory and Statistical Physics, Vol. 2, Issue. 1, p. 1.

Arumi, F. N. and Oakes, M. E. 1972. Absorption of an Electromagnetic Wave Normally Incident on a Warm Plasma. The Physics of Fluids, Vol. 15, Issue. 5, p. 837.

Nambu†, Mitsuhiro 1972. High-β effect on the generalized ion Berstein mode near the lower hybrid frequency. Journal of Plasma Physics, Vol. 7, Issue. 3, p. 503.

Palmer, F. H. and Barrington, R. E. 1973. Excitation of ion resonances by the Isis 2 HF transmitter. Journal of Geophysical Research, Vol. 78, Issue. 34, p. 8167.

Pesic, S S 1973. Damping of plasma waves in the lower hybrid frequency range. Plasma Physics, Vol. 15, Issue. 3, p. 193.

Schmitt, J. P. M. 1974. The magnetoplasma dispersion function: some mathematical properties. Journal of Plasma Physics, Vol. 12, Issue. 1, p. 51.

Ogino, T. and Takeda, S. 1974. Dispersion relation and eigenvectors of waves in plasmas. Electrical Engineering in Japan, Vol. 94, Issue. 5, p. 7.

Cuperman, S. and Gomberoff, L. 1977. Electromagnetic ion-cyclotron instability vs. electrostatic ion-cyclotron instability in mixed (warm-cold) magnetospheric-like plasmas. Journal of Plasma Physics, Vol. 18, Issue. 3, p. 391.

Stéfant, R. J. 1978. General dispersion relation for nonpotential ion harmonic waves propagating in plasmas with arbitrary β. The Physics of Fluids, Vol. 21, Issue. 1, p. 55.

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Structure of the Bernstein modes for large values of the plasma parameter

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This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Article contents

Structure of the Bernstein modes for large values of the plasma parameter

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