New Force, Global Anisotropy and the Changes in β-Decay Rate of Radioactive Elements
American Journal of Astronomy and Astrophysics
Volume 2, Issue 6-1, December 2014, Pages: 8-19
Received: Sep. 22, 2014; Accepted: Sep. 25, 2014; Published: Oct. 29, 2014
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Authors
Yuriy Alexeevich Baurov, Closed Joint Stock Company Research Institute of Cosmic Physics, 141070, Moscow Region, Pionerskaya, 4, Korolyov, Russia; Hotwater Srl, Via Gioberti, 15, I-56024 San Miniato (PI), Italy
Yuriy Grigoreyvich Sobolev, Joint Institute for Nuclear Researches, Moscow Region, Dubna, 141980, Russia; Nuclear Physics Institute, 250 68 Rez, Prague, Czech Republic
Yuriy Vasilevich Ryabov, Institute for Nuclear Research of Russian Academy of Science, 60 – the October Anniversary Prospect, 7a, Moscow 117312, Russia
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Abstract
The review of experimental studies results of a global anisotropy of physical space and new interaction in nature based on analyzing fluctuations in the intensity of the β-decay of radioactive elements are presented. The explanation of the results, based on a hypothesis as to the global anisotropy of physical space caused by the existence of cosmological vector potential AG in limits of theory of byuon, is given. It is shown that vector AG has the following coordinates in the second equatorial coordinate system: right ascension α = 293° ± 15°; declination δ = 36° ± 10°.
Keywords
Changes in β-Decay Rate of Radioactive Elements, Global Anisotropy, New Force
To cite this article
Yuriy Alexeevich Baurov, Yuriy Grigoreyvich Sobolev, Yuriy Vasilevich Ryabov, New Force, Global Anisotropy and the Changes in β-Decay Rate of Radioactive Elements, American Journal of Astronomy and Astrophysics. Special Issue:Global Anisotropy, Theory of Byuon, New Force, New Power System, Propulsion, Space Flights. Vol. 2, No. 6-1, 2014, pp. 8-19. doi: 10.11648/j.ajaa.s.2014020601.12
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