NS  Vol.3 No.2 , February 2011
Seismic activity of the earth, the cosmological vectorial potential and method of a short-term earthquakes forecasting
Abstract: To the foundation of a principally new short-term forecasting method there has been laid down a theory of surrounding us world’s creation and of physical vacuum as a result of interaction of byuons-discrete objects. The definition of the byuon contains the cosmological vector-potential Ag- a novel fundamental vector constant. This theory predicts a new anisotropic interaction of nature objects with the physical vacuum. A pe- culiar “tap” to gain new energy (giving rise to an earthquake) are elementary particles because their masses are proportional to the modulus of some summary potential A∑ that contains po- tentials of all known fields. The value of A∑ cannot be larger than the modulus of Ag. In ac- cordance with the experimental results a new force associated with A ejects substance from the area of the weakened A along a conical formation with the opening of 100° ± 10° and the axis directed along the vector A∑ . This vector has the following coordinates in the second equatorial coordinate system: right ascension α≈ 293°± 10°, declination δ≈36° ± 10°. The 100% probability of an earthquake (earthquakes of 6 points strong and more by the Richter scale) arises when in the process of the earth rotation the zenith vector of a seismically dangerous region and/or the vectorial potential of Earth’s magnetic fields are in a certain way oriented relative to the vector Ag. In the work, basic models and standard mechanisms of earth- quakes are briefly considered, results of proc- essing of information on the earthquakes in the context of global spatial anisotropy caused by the existence of the vector Ag, are presented, and an analysis of them is given.
Cite this paper: Alexeevich, B. , Yur’evich, B. , Yur’evich (Jr.), B. , Alfredovna, S. , Arshavirovich, A. and Alexandrovich, S. (2011) Seismic activity of the earth, the cosmological vectorial potential and method of a short-term earthquakes forecasting. Natural Science, 3, 109-119. doi: 10.4236/ns.2011.32016.

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