2013
DOI: 10.1063/1.4821606
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Study on longitudinal dispersion relation in one-dimensional relativistic plasma: Linear theory and Vlasov simulation

Abstract: The dispersion relation of one-dimensional longitudinal plasma waves in relativistic homogeneous plasmas is investigated with both linear theory and Vlasov simulation in this paper. From the Vlasov-Poisson equations, the linear dispersion relation is derived for the proper one-dimensional J€ uttner distribution. Numerically obtained linear dispersion relation as well as an approximate formula for plasma wave frequency in the long wavelength limit is given. The dispersion of longitudinal wave is also simulated … Show more

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Cited by 6 publications
(12 citation statements)
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“…It has to be highlighted that the Zhang dispersion relation (Zhang et al. 2013) described by the green line coincides with the red line until the effects of the real dispersion relations, which include the effects of the magnetic field and the - dimension case, are present. The Zhang dispersion relation is considered for a maximum wavenumber , arguing that it is sufficient for typical relativistic plasma oscillations and not because a cutoff is predicted as happens in our approach.…”
Section: Relativistic Dispersion Relation For the Longitudinal Casementioning
confidence: 95%
See 2 more Smart Citations
“…It has to be highlighted that the Zhang dispersion relation (Zhang et al. 2013) described by the green line coincides with the red line until the effects of the real dispersion relations, which include the effects of the magnetic field and the - dimension case, are present. The Zhang dispersion relation is considered for a maximum wavenumber , arguing that it is sufficient for typical relativistic plasma oscillations and not because a cutoff is predicted as happens in our approach.…”
Section: Relativistic Dispersion Relation For the Longitudinal Casementioning
confidence: 95%
“…The Fourier component of the -current vector is By using (3.5), we arrive at where and and where (see appendix B) where are is Kelvin function of order (Synge 1956) and It has to be noted that other works constrain the problem to one dimension and, consequently, they use the one-dimensional Jüttner distribution function (Zhang et al. 2013).…”
Section: Dispersion Relationsmentioning
confidence: 99%
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“…All computations are performed in normalized variables: the plasma frequency is use to set temporal and spatial scales; momenta are normalized to mc; the electric field is normalized to mcx p =e; and the background density n 0 scales out. Oscillations are excited by initializing the distribution function with a spatial modulation of wave number k f ðt ¼ 0; x; pÞ ¼ n 0 ð1 þ A cos kxÞf eq ðpÞ (22) with k ¼ 2pn=L, where n is an integer. We identify f ð1Þ ¼ A n 0 cosðkxÞ f eq ðpÞ.…”
Section: Examplesmentioning
confidence: 99%
“…For high-frequency electrostatic (plasma waves) and electromagnetic modes recent work has been developed in Refs. (Fichtner & Schlickeiser, 1995;Schlickeiser & Kneller, 1997;Melrose, 1999;Bergman & Eliasson, 2001;Podesta, 2008;Bers et al, 2009;Schlickeiser, 2010;Zhang et al, 2013;López et al;2014) in the context of laser thermonuclear fusion. Our work is therefore an extension of these works to low-frequency spectrum.…”
Section: Introductionmentioning
confidence: 99%