S. I. Fisenko^*, I. S. Fisenko, R. T. Rymkulov
Rusthermosynthesis JSC, Moscow, Russia.
DOI: 10.4236/jamp.2014.25001   PDF    HTML     3,806 Downloads   4,806 Views   Citations

Abstract

This report is a systematic and complemented summary of the earlier published works by the authors [1-4]. The concept of gravitational radiation as a radiation of one level with the electromagnetic radiation is based on theoretically proved and experimentally confirmed fact of existence of electron’s stationary states in own gravitational field, characterized by gravitational constant K = 1042 G (G—Newtonian gravitational constant) and by irremovable space-time curvature. The received results strictly correspond to principles of the relativistic theory of gravitation and the quantum mechanics. The given work contributes into further elaboration of the findings considering their application to dense high-temperature plasma of multiple-charge ions. This is due to quantitative character of electron gravitational radiation spectrum such that amplification of gravitational radiation may take place only in multiple-charge ion high-temperature plasma.

Keywords

Electron, Stationary States, Stable States, Pulse High-Current Discharge, Thermonuclear Fusion

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Conflicts of Interest

The authors declare no conflicts of interest.

References

[1]	Fisenko, S.I. and Fisenko, I.S. (2009) Gravitational Interaction on Quantum Level and Consequences Thereof. The Old and New Concepts of Physics, 6, 495-521.
[2]	Fisenko, S.I. and Fisenko, I.S. (2011) Gravitational Radiation of the Relativistic Theory of Gravitation. British Journal of Science, 2, 1-20.
[3]	Fisenko, S.I., Fisenko, I.S. (2012) The Discrete Energy Spectrum of the Gravitational Radiation in the Relativistic Theory of Gravitation. International Journal of Theoretical and Applied Physics (IJTAP), 2, 32-39.
[4]	Fisenko, S.I. and Fisenko, I.S. (2013) Method of Forming Stable States of Dense High-Temperature Plasma. Journal of Modern Physics, 4, 481-485.
[5]	Siravam, C. and Sinha, K. (1979) The Concept of “Strong” Gravity. Physics Reports, 51, 112-123.
[6]	Ivanenko, D.D., et al. (1985) Gauge Theory of Gravity. MGU Publishing House, Moscow, 71-73.
[7]	Landau, L.D. and Lifshitz, E.M. (1976) Field Theory. Publishing House “Nauka”, Moscow, 451-457.
[8]	Warshalovich, D.A., et al. (1975) Quantum Theory of Angular Momentum. Publishing House “Nauka”, Leningrad, 282-285.
[9]	Wu, Z.S. and Moshkovsky, S.A. (1970) b-Decay. Atomizdat, Moscow, 121-135.
[10]	Haines, M.G., et al. (2006) Viscous Heating at Stagnation in Z-Pinches. PRL, 96, 075003-075008.
[11]	Cullen, D.E., et al., (1994) Report IAEA—NDS-158.
[12]	Burenkov, O.M., Dolin, Y.N., Duday, P.V., Dudin, V.I., Ivanov, V.A., Ivanovsky, A.V., Karpov, G.V., et al. (2012) New Сonfiguration of Experiments for MAGO Program, XIV International Conference on Megagauss Magnetic Field Generation and Related Topics, October 14-19, 2012, Maui, Havaii, 95-99.
[13]	Fissenko, S. and Fissenko, I. (2005) (IPN WO2005/109970 A1): Method of Forming Stable States of Dense High- Temperfature Plasma. PCT Gazette No. 46, 553.