American Journal of Astronomy and Astrophysics
Volume 2, Issue 6-1, December 2014, Pages: 32-39
Received: Nov. 4, 2014;
Accepted: Nov. 6, 2014;
Published: Nov. 10, 2014
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Francesco Meneguzzo, National Research Council – Institute of Biometeorology, 8, Via G. Caproni, I-50145Firenze, Italy
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
Lorenzo Albanese, National Research Council – Institute of Biometeorology, 8, Via G. Caproni, I-50145Firenze, Italy
Following earlier research aimed at detecting evidence of a connection between selected very powerful tornadoes and the global anisotropy of the physical space representing the foundation of the theory of byuons, allegedly realized by means of a positive feedback between the tornado updraft and the cosmological vector representing the global anisotropy, this article extends the analysis to a much larger database of tornadic events occurring in the continental U.S. in order to detect the fingerprint of the new proposed physical processes on the overall statistics. While the theoretical foundations of the onset and development of tornadoes are well established, some work remains to be done with particular reference to the upper tail of the energy distribution of tornadoes, where the energy developed by a single event can be as huge as 1016 J, or the equivalent of 2 Mton of TNT. In this range, additional mechanisms of energy supply in the process of development of a tornado are proposed and their fingerprint on the overall statistics are looked for. Although further analyses over different geographical areas, especially in the southern hemisphere, would be needed in order to provide a really conclusive proof, convincing evidence accumulates and points to the reality of the new proposed physical processes.
Yuriy Alexeevich Baurov,
A New Additional Energy Source for Tornadoes, 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. 32-39.
S.A. Arsen’yev, Mathematical modeling of tornadoes and squall storms, Geosci. Front. 2 (2011) 215–221.
S.A. Arsen’yev, N.K. Shelkovnikov, Electromagnetic fields in tornados and spouts, Moscow Univ. Phys. Bull. 67 (2012) 290–295.
A.Y. Gubar, A.I. Avetisyan, V. V Babkova, Tornado rise: 3D numerical model in the mesoscale turbulence theory of Nikolaevskiy, Dokl. Earth Sci. 419 (2008) 467–472.
N. Kufa, R. Snow, Lightning: meteorology’s new tool, in: 86th AMS Annu. Meet. (Atlanta, GA). Second Conf. Meteorol. Appl. Light. Data, American Meteorological Society, 2006.
A.J. Litta, U.C. Mohanty, S. Kiran Prasad, M. Mohapatra, A. Tyagi, S.C. Sahu, Simulation of tornado over Orissa (India) on March 31, 2009, using WRF–NMM model, Nat. Hazards. 61 (2011) 1219–1242.
A.E. Mercer, C.M. Shafer, C.A. Doswell, L.M. Leslie, M.B. Richman, Objective Classification of Tornadic and Nontornadic Severe Weather Outbreaks, Mon. Weather Rev. 137 (2009) 4355–4368.
L. Schielicke, P. Névir, Comprehensive analysis of tornado statistics in comparison to earthquakes: intensity and temporal behaviour, Nonlinear Process. Geophys. 20 (2013) 47–57.
Y.A. Baurov, I.F. Malov, F. Meneguzzo, Tornadoes and the global anisotropy of the physical space, Am. J. Mod. Phys. 3 (2014) 93–112.
SPC, Storm Prediction Center — severe weather database files (1950–2013), (2013).
M. V Kurgansky, The statistical distribution of intense moist-convective, spiral vortices in the atmosphere, Dokl. Earth Sci. 371 (2000) 408–410.
L. Schielicke, P. Névir, Introduction of an atmospheric moment combining Eulerian and Lagrangian aspects of vortices: Application to tornadoes, Atmos. Res. 100 (2011) 357–365.
Y.A. Baurov, E.Y. Klimenko, S.I. Novikov, Experimental observation of space magnetic anisotropy, Phys. Lett. A. 162 (1992) 32–34.
Y.A. Baurov, Space magnetic anisotropy and a new interaction in nature, Phys. Lett. A. 181 (1993) 283–288.
Y.A. Baurov, A.A. Konradov, V.F. Kushniruk, E.A. Kuznetsov, Y.G. Sobolev, Y. V. Ryabov, et al., Experimental investigations of changes in beta-decay rate of 60Co and 137Cs, Mod. Phys. Lett. A. 16 (2001) 2089–2101.
I.F. Malov, Y.A. Baurov, The distribution of space velocities of radio pulsars, Astron. Reports. 51 (2007) 830–835.
Y.A. Baurov, The Anisotropy of Cosmic Rays and the Global Anisotropy of Physical Space, J. Mod. Phys. 03 (2012) 1744–1748.
Y.A. Baurov, On the structure of physical vacuum and a new interaction in Nature (Theory, Experiment and Applications), Nova Science, NY, 2000.
Y.A. Baurov, Global Anisotropy of Physical Space, Experimental and Theoretical Basis, Nova Science, NY, 2004.
Y.A. Baurov, I.F. Malov, On the Nature of Dark Matter and Dark Energy, J. Mod. Phys. 01 (2010) 17–32.
Y.A. Baurov, Research of global anisotropy of physical space based on investigation of changes in β and α-decay rate of radioactive elements , motion of pulsars and anisotropy of cosmic rays, Am. J. Mod. Phys. 2 (2013) 177–184.
Y.A. Baurov, I.F. Malov, Variations of Decay Rates of Radio-active Elements and their Connections with Global Anisotropy of Physical Space, Int. J. Pure Appl. Phys. 6 (2010) 469–482. Also at: http://arxiv.org/abs/1001.5383.
Y.A. Baurov, I.B. Timofeev, V.A. Chernikov, S.F. Chalkin, A.A. Konradov, Experimental investigations of the distribution of pulsed-plasma-generator radiation at its various spatial orientation and global anisotropy of space, Phys. Lett. A. 311 (2003) 512–523.
Y.A. Baurov, Y.G. Sobolev, Y. V. Ryabov, V.F. Kushniruk, Experimental investigations of changes in the rate of beta decay of radioactive elements, Phys. At. Nucl. 70 (2007) 1825–1835.
P.A. Sturrock, J.B. Buncher, E. Fischbach, D. Javorsek II, J.H. Jenkins, J.J. Mattes, Concerning the Phases of the Annual Variations of Nuclear Decay Rates, Astrophys. J. 737 (2011) 65.
Y.A. Baurov, A.A. Spitalnaya, A.A. Abramayan, V.A. Solodovnikov, Seismic activity of the earth, the cosmological vectorial potential and method of a short-term earthquakes forecasting, Nat. Sci. 03 (2011) 109–119.
Y.A. Baurov, F. Meneguzzo, A.Y. Baurov, A.Y.J. Baurov, Plasma Vacuum Bubbles and a New Force of Nature , The Experiments, Int. J. Pure Appl. Sci. Technol. 11 (2012) 34–44.
Y.A. Baurov, L. Albanese, F. Meneguzzo, New force and new heat, Am. J. Astron. Astrophys. (in press) (2014) Special Issue: Global Anisotropy, Theory of Byuon.