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The Practically Confirmed Validity of the Forecasting Aspects of the Deterministic Thermohydrogravidynamic Theory
Current Issue
Volume 2, 2015
Issue 5 (September)
Pages: 106-122   |   Vol. 2, No. 5, September 2015   |   Follow on         
Paper in PDF Downloads: 26   Since Sep. 3, 2015 Views: 1978   Since Sep. 3, 2015
Authors
[1]
Sergey V. Simonenko, V.I. Il’ichev Pacific Oceanological Institute, Far Eastern Branch of Russian Academy of Sciences, Vladivostok, Russia.
Abstract
The article presents the development of the cosmic geophysics (representing the deterministic thermohydrogravidynamic theory based on the author’s generalized differential formulation of the first law of thermodynamics) by demonstrating the evidence of the predominant combined cosmic solar-lunar energy gravitational mechanism of triggering of the prepared earthquakes. The author presents the practically confirmed (by the realized intensification of the Japanese seismic activity including the Tokyo region during 25 - 30 May, 2015 AD) validity of the forecasting aspects of the deterministic thermohydrogravidynamic theory by evaluating in advance (in 2014 AD) the “first forthcoming range 2015÷2023÷2027.7 of the possible intensification of the Japanese seismic activity (including the Tokyo region)” based on the previous strong earthquakes near the Tokyo region.
Keywords
Cosmic Geophysics, Thermohydrogravidynamic Theory, Generalized First Law of Thermodynamics, Earthquakes Prediction, Tokyo and Near Tokyo Region
Reference
[1]
Richter CF. Elementary Seismology, San Francisco, USA: W.H. Freeman, 1958.
[2]
Vikulin AV. Physics of Wave Seismic Process, Petropavlovsk-Kamchatsky, A. V. Nikolaev, Ed. Russia: the Kamchatsky State Pedagogical University Press, 2003. In Russian.
[3]
Simonenko SV. Thermohydrogravidynamics of the Solar System, G. Sh. Tsitsiashvili, Ed. Nakhodka, Russia: Institute of Technology and Business Press, 2007.
[4]
Simonenko SV. Fundamentals of the Thermohydrogravidynamic Theory of Cosmic Genesis of the Planetary Cataclysms, G. Sh. Tsitsiashvili, Ed. Nakhodka, Russia: Institute of Technology and Business Press, 2009.
[5]
Simonenko SV. Fundamentals of the Thermohydrogravidynamic Theory of Cosmic Genesis of the Planetary Cataclysms, 2nd ed., G. Sh. Tsitsiashvili Ed. Nakhodka, Russia: Institute of Technology and Business Press, 2010.
[6]
Sagiya T. Integrate all available data. Nature. 2011; 473: 146-147.
[7]
Yagi Y. Enhance ocean – floor observation. Nature. 2011; 473: 147-148.
[8]
Console R. Yamaoka K, Zhuang J. Implementation of short- and medium-term earthquake forecasts. International Journal of Geophysics. 2012; vol. 2012, article ID 217923, 2 pages, 2012, doi:10.1155/2012/217923.
[9]
Sgrigna V, Conti L. A deterministic approach to earthquake prediction. International Journal of Geophysics. 2012; vol. 2012, article ID 406278, 20 pages, 2012, doi:10.1155/2012/406278.
[10]
Tinivella U, Giustiniani M, Cassiani G. Geophysical Methods for Environmental Studies. International Journal of Geophysics. 2013; vol. 2013, Article ID 950353, 2 pages, 2013. Available: http://dx.doi.org/10.1155/2013/950353
[11]
Simonenko SV. Fundamentals of the thermohydrogravidynamic theory of the global seismotectonic activity of the Earth. International Journal of Geophysics. 2013; vol. 2013, Article ID 519829, 39 pages, 2013. Available: http://dx.doi.org/10.1155/2013/519829
[12]
Simonenko SV. Statistical thermohydrodynamics of irreversible strike-slip-rotational processes. In Rotational Processes in Geology and Physics. pp. 225–251, E. E. Milanovsky Ed. Moscow, Russia: KomKniga, 2007. In Russian.
[13]
Gibbs JW. Graphical methods in the thermodynamics of fluids. Transactions of the Connecticut Academy. 1873; 2: 309–342.
[14]
Landau LD, Lifshitz EM. Theoretical Physics. Vol. 5. Statistical Physics, V.D. Kozlov Ed. Moscow, Russia: Nauka, 1976. In Russian.
[15]
Simonenko SV. The Cosmic Energy Gravitational Genesis of the Increase of the Seismic and Volcanic Activity of the Earth in the Beginning of the 21st Century AD. G. Sh. Tsitsiashvili Ed. Nakhodka, Russia: Institute of Technology and Business Press, 2012.
[16]
Simonenko SV. The practical forecasting aspects of the thermohydrogravidynamic theory of the global seismotectonic activity of the Earth concerning to the Japanese earthquakes near the Tokyo region. American Journal of Earth Sciences. 2014; 1 (2): 38-61.
[17]
Simonenko SV. The linkage of the different distinct great volcanic eruptions of the Thera (Santorini) in the range (1700÷1450±14) BC and the related subsequent intensifications of the global seismicity and volcanic activity in the end of the 19th century and in the beginning of the 20th century, in the end of the 20th century, and in the beginning of the 21st century AD. Journal of Advances in Physics. 2014; 4 (2): 484-516.
[18]
Simonenko SV. The prognosticating aspects of the developed cosmic geophysics concerning the subsequent forthcoming intensifications of the global seismicity, volcanic and climatic activity of the Earth in the 21st century. British Journal of Applied Science & Technology. 2014; 4 (25): 3563-3630.
[19]
Simonenko SV. The evidence of the cosmic energy gravitational genesis of the forthcoming intensification of the global seismotectonic, volcanic, climatic and magnetic activity of the Earth, and the problem of the controlled thermonuclear reactions. International Journal of Latest Research in Science and Technology. 2014; 3 (3): 206-214.
[20]
Simonenko SV. Fundamentals of the non-equilibrium statistical thermohydrodynamic theory of the small-scale dissipative turbulence and the deterministic thermohydrogravidynamic theory of the glogal seismotectonic, volcanic and climatic activity of the Earth. International Journal of Engineering Science Invention. 2014; 3 (10) : 22-58.
[21]
Simonenko SV. The evidence of the cosmic energy gravitational genesis of the possible forthcoming geomagnetic reversal of the magnetic field of the Earth. International Journal of Engineering Science and Innovative Technology. 2014; 3 (6): 568-585.
[22]
Jackson A. A new turn for Earth’s rotation. Nature. 2010; 465: 39–40.
[23]
Stein RS, Toda S. Megacity megaquakes – two near misses. Science. 2013; 341: 850–852.
[24]
Landau LD, Lifshitz EM. Theoretical Physics. Vol. 6. Hydrodynamics, Yu. G. Rudoy Ed. Moscow, Russia: Nauka, 1988. In Russian.
[25]
De Groot SR, Mazur P. Non-equilibrium Thermodynamics, Amsterdam, Holland: North-Holland Publishing Company, 1962.
[26]
Gyarmati I. Non-equilibrium Thermodynamics. Field Theory and Variational Principles, Germany, Berlin: Springer-Verlag, 1970.
[27]
Simonenko SV. The macroscopic non-equilibrium kinetic energies of a small fluid particle. Journal of Non-Equilibrium Thermodynamics. 2004; 29 (2): 107–123.
[28]
Simonenko SV. Non-equilibrium Statistical Thermohydrodynamics of Turbulence, G. I. Dolgikh Ed., Moscow, Russia: Nauka, 2006.
[29]
Vikulin AV. The World of the Vortical Motions. G.F. Mayorova Ed. Petropavlovsk-Kamchatsky, Russia: the Kamchatsky State Technical University Press, 2008.
[30]
Dolgikh GI, Kuptsov AV, Larionov IA, et al. Deformation and acoustic precursors of earthquakes. Doklady Earth Sciences. 2007; 413 (1): 96–100. In Russian.
[31]
Lamb H. Higher Mechanics, 2nd ed. Cambridge, UK: Cambridge University press, 1929.
[32]
Alboussière T, Deguen R, Melzani M. Melting-induced stratification above the Earth’s inner core due to convective translation. Nature. 2010; 466: 744–747.
[33]
Straser V. Variations in gravitational field, tidal force, electromagnetic waves and earthquakes. New Concepts in Global Tectonics Newsletter. 2010; 57: 98-108.
[34]
Avsjuk YN. Tidal Forces and Natural Processes. Moscow, Russia: UIPE RAS; 1996. In Russian.
[35]
Tsuboi C. The gravitational field of the Earth. Moscow, Russia: Mir, 1982. In Russian.
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