New Horizons in Mathematical Physics

Download PDF (1080.9 KB) PP. 13 - 52 Pub. Date: June 1, 2019

DOI: 10.22606/nhmp.2019.32001

• Sergey V. Simonenko^*
  V.I. Il’ichev Pacific Oceanological Institute, Far Eastern Branch of Russian Academy of Sciences, 43 Baltiyskaya St., Vladivostok, 690041, Russia

The article presents the subsequent development of the established thermohydrogravidynamic theory (intended for deterministic prediction of the temporal intensifications of the global and regional seismotectonic, volcanic and climatic activity of the Earth) based on the author’s generalized differential formulation of the first law of thermodynamics extending the classical Gibbs’ formulation by taking into account (along with the classical infinitesimal change of heat δQ and the classical infinitesimal change of the internal thermal energy dUτ) the established differential energy gravitational influence dG (due to the cosmic and terrestrial non-stationary gravitation) on the continuum region τ along with the established differential increment dKτ of the macroscopic kinetic energy, the established differential increment dΠτ of the gravitational potential energy and the established generalized expression for the differential work δAnp,∂τ done by the non-potential terrestrial stress forces (determined by the symmetric stress tensor T) acting on the boundary surface ∂τ of the individual finite continuum region τ subjected to the non-stationary Newtonian gravitation. Taking into account the combined solar and planetary integral energy gravitational influence of the internal rigid core τc,r of the Earth τ3 during the considered range (2004 ÷ 2026) AD, the author presents (on May 30, 2018) the foundation (based on the established and confirmed global prediction thermohydrogravidynamic principles determining the strongest temporal intensifications of the global and regional seismotectonic, volcanic and climatic activity of the Earth) of the established first forthcoming subrange (2020 ÷ 2026) AD of the increased intensification of the global seismotectonic, volcanic, climatic and magnetic activity of the Earth related with the maximal (near t*(τc,r, 2021)=2021.1 AD)) and the minimal (near t*(τc,r, 2021)=2021.65 AD)) combined cosmic (planetary and solar) integral energy gravitational influences on the internal rigid core of the Earth.

Thermohydrogravidynamic theory, generalized formulation of the first law of thermodynamics, non-stationary cosmic gravitation, global seismicity, global volcanic and climatic activity, natural disasters of the Earth.

[1] C. F. Richter, Elementary Seismology, W.H. Freeman, San Francisco, Calif, USA, 1958.

[2] V. Sgrigna and L. Conti, “A deterministic approach to earthquake prediction,” International Journal of Geophysics, vol. 2012, article ID 406278, 20 pages, 2012.

[3] R. Console, K. Yamaoka, and J. Zhuang “Implementation of short- and medium-term earthquake forecasts,” International Journal of Geophysics, vol. 2012, article ID 217923, 2 pages, 2012.

[4] S. V. Simonenko, Non-Equilibrium Statistical Thermohydrodynamics of Turbulence, Nauka, Moscow, 2006.

[5] S. V. Simonenko, “Statistical thermohydrodynamics of irreversible strike-slip-rotational processes,” in Rotational Processes in Geology and Physics, pp. 225–251, KomKniga, Moscow, Russia, 2007, In Russian.

[6] S. V. Simonenko, Thermohydrogravidynamics of the Solar System, Institute of Technology and Business Press, Nakhodka, Russia, 2007.

[7] S. V. Simonenko, Fundamentals of the Thermohydrogravidynamic Theory of Cosmic Genesis of the Planetary Cataclysms, Institute of Technology and Business Press, Nakhodka, Russia, 2009.

[8] S. V. Simonenko, Fundamentals of the Thermohydrogravidynamic Theory of Cosmic Genesis of the Planetary Cataclysms, Institute of Technology and Business Press, Nakhodka, Russia, 2nd edition, 2010.

[9] J. W. Gibbs, “Graphical methods in the thermodynamics of fluids,” in Transactions of the Connecticut Academy, vol. 2, pp. 309–342, 1873.

[10] Y. Zhu and F. B. Zhan, “Medium-term earthquake forecast using gravity monitoring data: evidence from the Yutian and Wenchuan earthquakes in China,” International Journal of Geophysics, vol. 2012, article ID 307517, 6 pages, 2012.

[11] F. B. Zhan, Y. Zhu, J. Ning, J. Zhou, W. Liang, and Y. Xu, “Gravity changes before large earthquakes in China: 1998–2005,” Geo-Spatial Information Science, vol. 14, no. 1, pp. 1–9, 2011.

[12] T. Matuzawa, “On the possibility of gravitational waves in soil and allied problems,” Japanese Journal of Astronomy and Geophysics, vol. 3, pp. 161–177, 1925.

[13] C. Lomnitz and H. Castanos, “Earthquake hazard in the valley of Mexico: entropy, structure, complexity,” in Earthquake Source Asymmetry, Structural Media and Rotation Effects, pp. 347–364, Springer, New York, NY, USA, 2006.

[14] C. Lomnitz, “Some observations of gravity waves in the 1960 Chile earthquake,” Bulletin of the Seismological Society of America, vol. 59, no. 2, pp. 669–670, 1970.

[15] C. Lomnitz, “Mexico 1985: the case for gravity waves,” Geophysical Journal International, vol. 102, no. 3, pp. 569–572, 1990.

[16] A. V. Vikulin, The World of the Vortical Motions, The Kamchatsky State Technical University Press, Petropavlovsk-Kamchatsky, Russia, 2008, In Russian.

[17] A. V. Vikulin, Seismicity, Volcanism and Geodynamics. The Selected Works, The Kamchatsky State University Press, Petropavlovsk-Kamchatsky, Russia, 2011, In Russian.

[18] S. V. Simonenko, “Fundamentals of the thermohydrogravidynamic theory of the global seismotectonic activity of the Earth,” International Journal of Geophysics, vol. 2013, article ID 519829, 39 pages, 2013.

[19] S. V. Simonenko, 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, Institute of Technology and Business Press, Nakhodka, Russia, 2012.

[20] S. V. Simonenko, “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, vol. 4, no. 25, pp. 3563–3630, 2014.

[21] S. V. Simonenko, “The confirmed validity of the thermohydrogravidynamic theory concerning the strongest intensifications of the global natural processes of the Earth in 2016 since 1 September, 2016,” British Journal of Applied Science & Technology, vol. 18, no. 5, pp. 1–20, 2016. Article no.BJAST.30049.

[22] Associated Press. Hurricane Matthew is getting stronger. Oct. 6, 2016. AM. Available: http://www. businessinsider.com/hurricane-matthew-getting-stronger-2016-10

[23] S. V. Simonenko, “The confirmed validity of the thermohydrogravidynamic theory concerning the first subrange of the strongest intensifications of the global natural processes of the Earth in 2017 since 10 April, 2017 and before 6 August, 2017,” Transylvanian Review, vol. XXV, no. 20, pp. 5049–5058, 2017.

[24] S. V. Simonenko, “The confirmed validity of the predictions of the thermohydrogravidynamic theory concerning the strongest intensifications of the seismotectonic and climatic processes in California (since 9 August, 2017 and before 3 March, 2018) and in Japan since 24 July, 2017 and before 16 March, 2018,” Current Science, vol. 114, no. 7, pp. 301–324, 2017.

[25] S. V. Simonenko, “The prediction of the thermohydrogravidynamic theory concerning the strongest intensifications of the seismotectonic and climatic processes in California since 9 August, 2017 and before 3 March, 2018,” International Journal of Research – Granthaalayah, vol. 5, no. 10, pp. 137–159, 2017.

[26] S. V. Simonenko, “The cosmic gravitational genesis of the predicted intensifications of global natural processes since 10 April, 2017 and before 26 February, 2018,” American Journal of Earth Sciences, vol. 4, no. 3, pp. 32–47, 2017.

[27] S. V. Simonenko, “The confirmed cosmic energy gravitational genesis of the strongest Japanese, Italian, Greek, Chinese and Chilean earthquakes,” Energy Research, vol. 2, pp. 1–32, 2018.

[28] F. J. Raab and D. H. Reitze, “The first direct detection of gravitational waves opens a vast new frontier in astronomy,” Current Science. vol. 113, no. 4, pp. 657–662, 2017.

[29] S. Dhurandhar, and B. S. Sathyaprakash, “Cosmic sirens: discovery of gravitational waves and their impact on astrophysics and fundamental physics,” Current Science. vol. 113, no. 4, pp. 663–671, 2017.

[30] Cassius Dio Cocceianus, Dio’s Roman History, with an English translation by Earnest Cary, PH.D., on the basis of the version of Herbert Baldwin Foster, PH.D. In nine volumes. vol. 3. Available: http://www.archive.org/ details/diosromanhistory03cassuoft (accessed December 30, 2010).

[31] Von Bunsen, Aegypten’s Stelle in der Weltgeschichte, 1845–57, 5 vols; Engl. tr. by C.H. Сottrell as Egypt’s Place in Universal History, London, UK, 1848–67, 5 vols.

[32] G. Hancock, Fingerprints of the Gods, Publishing Office “Veche”, Moscow, Russia, 1997, In Russian.

[33] L. D. Landau and E. M. Lifshitz, Theoretical Physics, vol. 5 of Statistical Physics, Nauka, Moscow, Russia, 1976, In Russian.

[34] C. Truesdell and W. Noll, The Nonlinear Field Theories of Mechanics. In: S. Flügge, (ed) Handbuch der Physik, vol III/3. Springer-Verlag, Berlin, 1965.

[35] C. Truesdell, A First Course in Rational Continuum Mechanics. Publishing Office “Mir”, Moscow, Russia, 1975, In Russian.

[36] G. K. Batchelor, An Introduction to Fluid Dynamics, Cambridge University Press, Cambridge, UK, 1967.

[37] S. R. De Groot and P. Mazur, Non-Equilibrium Thermodynamics, North-Holland, Amsterdam, The Netherlands, 1962.

[38] I. Gyarmati, Non-Equilibrium Thermodynamics. Field Theory and Variational Principles, Springer-Verlag, Berlin, 1970.

[39] J. D. Clayton, Nonlinear Mechanics of Crystals, Springer, Dordrecht, 2011.

[40] A. V. Zhirmunsky and V. I. Kuzmin, Critical Levels in the Development of Natural Systems, Nauka, Leningrad, Russia, 1990, In Russian.

[41] Y. N. Avsjuk, Tidal Forces and Natural Processes, UIPE RAS, Moscow, Russia, 1996, In Russian.

[42] A. V. Vikulin, Physics of Wave Seismic Process, The Kamchatsky State Pedagogical University Press, Petropavlovsk-Kamchatsky, Russia, 2003. In Russian.

[43] G. I. Dolgikh, The Investigations of the Wave Fields of the Ocean and Lithosphere by Laser-Interference Methods, Dalnauka, Vladivostok, Russia, 2000, In Russian.

[44] V. A. Abramov, “Forecasting of disastrous earthquakes,” Proceedings of the Vladivostok Professor’s Club, no. 1, pp. 64–77, 1997, In Russian.

[45] B. F. Chao and R.S. Gross, “Changes in the Earth’s rotation and low-degree gravitational field induced by earthquakes,” Geophysical Journal of the Royal Astronomical Society, vol. 91, no. 3, pp. 569–596, 1987.

[46] B. F. Chao and R.S. Gross, “Changes in the Earth’s rotational energy induced by earthquakes,” Geophysical Journal International, vol. 122, no.3, pp. 776–783, 1995.

[47] B. F. Chao, R.S. Gross, and D-N Dong, “Changes in global gravitational energy induced by earthquakes,” Geophysical Journal International, vol. 122, no. 3, pp. 784–789, 1995.

[48] C. U. Hammer, H. B. Clausen, and W. Dansgaard, “Greenland ice sheet evidence of post-glacial volcanism and its climatic impact,” Nature, vol. 288, pp. 230–235, 1980.

[49] Y. I. Perelman, Entertaining Astronomy, State Publishing Office of the Technical-Theoretical Literature, Moscow, Russia, 1956, In Russian.

[50] H. Alfven and G. Arrhenius, Evolution of the Solar System. Publishing Office “Mir”, Moscow, Russia, 1979, In Russian.

[51] A. Goncharova, S. Gorbarenko, X. Shi, A. Bosin, V. Fischenko, J. Zou, and Y. Liu, “Millennial – centennial – interdecadal scale climate and environmental changes of the Japan Sea sediments over the last 60 thousand years: investigation based on wavelet analysis,” in Abstracts of the 2nd Russia-China Symposium on Marine Science: Marine Environmental and Resources in 21st Century, pp. 53–54, FEB RAS, Vladivostok, Russia, October 2012.

[52] I. Kalugin and A. Darin, “High resolution geochemical signal of paleoclimate in the bottom sediments based on scanning x-ray fluorescence analysis on synchrotron radiation (XRF SR),” in Abstracts of the 2nd Russia-China Symposium on Marine Science: Marine Environmental and Resources in 21st Century, p. 70, FEB RAS, Vladivostok, Russia, October 2012.

[53] S. V. Simonenko, “Fundamentals of the thermohydrogravidynamic theory of the global seismotectonic, volcanic and climatic variability of the Earth,” in Abstracts of the 2nd Russia-China Symposium on Marine Science: Marine Environmental and Resources in 21st Century, pp. 165–166, FEB RAS, Vladivostok, Russia, October 2012.

[54] V. C. LaMarche and K. K. Hirschboeck, “Frost rings in trees as records of major volcanic eruptions,” Nature, vol. 307, pp. 121–126, 1984.

[55] T. Thordarson and G. Larsen, “Volcanism in Iceland in historical time: Volcano types, eruption styles and eruptive history,” Journal of Geodynamics, vol. 43, pp. 118–152, 2007.

[56] P. E. LaMoreaux, “Worldwide environmental impacts from the eruption of Thera,” Earth and Environmental Science, Environmental Geology, vol. 26, no. 3, pp. 172–181, 1995.

[57] C. Chandler, “On the variation of the latitude,” Astronomical Journal, vol. 11, pp. 97–107, 1892.

[58] S. V. Simonenko, “The cosmic energy gravitational genesis of the forthcoming intensifications of the global seismotectonic, volcanic, climatic and magnetic activities since 2016 AD,” American Journal of Earth Sciences, vol. 2, no. 6, pp. 211–229, 2015.

[59] T. Alboussière, R. Deguen, and M. Melzani, “Melting-induced stratification above the Earth’s inner core due to convective translation,” Nature, vol. 466, pp. 744–747, 2010.

[60] A. Sommerfeld, Vorlesungen über Theoretische Physic. Bd. 2I. Mechanik der Deformierbaren Medien, 2. Neubearb, Aufl, Leipzig, Germany, 1949.

[61] L. D. Landau and E.M. Lifshitz, Theoretical Physics, vol. 6 of Hydrodynamics, Nauka, Moscow, Russia, 1988, In Russian.

[62] S. V. Simonenko, “The macroscopic non-equilibrium kinetic energies of a small fluid particle,” Journal of Non- Equilibrium Thermodynamics, vol. 29, no. 2, pp. 107–123, 2004.

[63] S. V. Simonenko, “The practically confirmed validity of the forecasting aspects of the deterministic thermohydrogravidynamic theory,” American Journal of Earth Sciences, vol. 2, no. 5, pp. 105–122, 2015.