Transverse Plasma Resonans Mode in an Nonmagnetized Plasma and Its Practical Applications

F. F. Mende

American Journal of Electrical and Electronic Engineering. 2014, 2(5), 152-158
DOI: 10.12691/AJEEE-2-5-3

Original Research

Transverse Plasma Resonans Mode in an Nonmagnetized Plasma and Its Practical Applications

F. F. Mende^1,

¹B.I. Verkin Institute for Low Temperature Physics and Engineering, NAS Ukraine, 47 Lenin Ave., Kharkov, Ukraiua

Pub. Date: November 02, 2014

Full Text PDF

Cite this paper

F. F. Mende. Transverse Plasma Resonans Mode in an Nonmagnetized Plasma and Its Practical Applications. American Journal of Electrical and Electronic Engineering. 2014; 2(5):152-158. doi: 10.12691/AJEEE-2-5-3

Abstract

Is shown that in the nonmagnetized plasma, besides longitudinal Langmuir resonance can exist the transverse plasma resonance. The resonance indicated can exist in the confined plasma. It is known that with the nuclear explosions the electromagnetic radiation in the very wide frequency band is observed, up to the radio-frequency range. And if the emission in field of light range can be explained by the emission of separate atoms, then emission in the region of radio-frequency band can be caused only by collective processes, which occur in the confined plasma. The use of transverse resonance makes it possible to create resonators and band-pass filters, and also lasers on the collective plasma oscillations. Transverse plasma resonance can be used also for the warming-up of plasma and its diagnostics. Is introduced the concept of magnetoelectrokinetic waves.

Keywords

plasma, resonance, Langmuir resonance, plasma resonance, cavity, laser

Copyright

This work is licensed under a Creative Commons Attribution 4.0 International License. To view a copy of this license, visit http://creativecommons.org/licenses/by/4.0/

References

[1]	V. L. Ginzburg, The propagation of electromagnetic waves in a plasma.-M.: Science. 1967.

[2]	A. I. Akhiezer, Plasma Physics Nauka, Moscow, 1974.

[3]	A. F. Aleksandrov, L.S. Bogdankevich, A. A. Rukhdze, Oscillations and waves in plasma media, Moscow University Publishers, 1990.

[4]	A. A. Artsimovich, R. Z. Sagdeev, Plasma Physics for Physicists. M: Atomizdat, 1979.

[5]	F.F. Mende, A.I. Spitsyn, Surface impedance in superconductors, Kiev, Naukova Dumka, 1985.

[6]	F. F. Mende, Role and place of the kinetic inductance of charges in classical electrodynamics, Engineering Physics, № 11, 2012.

[7]	F. F. Mende, On refinement of equations of electromagnetic induction, Kharkov, deposited in VINITI, No 774-B88 Dep., 1988.

[8]	F. F. Mende, Are there errors in modern physics. Kharkov, Constant, 2003.

[9]	F.F. Mende, On refinement of certain laws of classical electrodynamics,arXiv.org/abs/physics/0402084.

[10]	F. F. Mende, Consistent electrodynamics, Kharkov NTMT, 2008.

[11]	F. F. Mende, Consistent electrodynamics and the threat of nuclear Space terrorism. Kharkov NTMT, 2008.

[12]	F. F. Mende, Great misconceptions and errors physicists XIX-XX centuries. Revolution in modern physics, Kharkiv NTMT, 2010.

[13]	F. F. Mende New electrodynamics, Revolution in modern physics. Kharkov NTMT, 201.

[14]	F. London, Superfluids. Vol.1. Microscopic theory of superconductivity.-Nev York: Dower publ., 1950.

[15]	L. D. Landau, E.M. Lifshits, Electrodynamics of continuous media. Moscow 1973.

[16]	F. F. Mende, Transversal plasma resonance in a nonmagnetized plasma and possibilities of practical employment of it, arXiv.org/abs/physics/0506081.

[17]	A.Yriv, Quantum electrodynamics and nonlinear optics. Sov. Radio: Moscow 1973.