Energy metrics and their Ricci flows
Article Sidebar
Main Article Content
Abstract
The framework of the Deformed Space-Time theory has been extended in the past from four to five dimensions, where the fifth coordinate is the energy exchanged by the interaction. In this theory, each fundamental interaction is described by an energy-dependent metric.
This picture has been exploited in order to take care of the interaction behaviour both when Lorentz invariance holds and the spacetime is Minkowskian and when Lorentz is violated and must be recovered in a non-minkowskian spacetime.
It has been successfully attempted to complete the pentadimensional metric of the four fundamental interactions calculating the fifth element of the metric corresponding to the fifth coordinate energy.
The mathematical tool exploited is the method of the Ricci flow which gave the complete explicit form of the fifth element of the metric, answering in this way the question of "how the energy measure the energy" for each interaction, setting the electromagnetic interaction as the reference for the energy measure. In this sense it has been given meaning to the problem of the energy gauge for interaction, identifying the gauge with the fifth metric element.
The consequences of the nuclear metamorphosis have been also examined for reaching the technological goal of a device stably producing this metamorphosis under the hadronic metric. The most valuable consequence is that in this pentadimensional picture, the old Einsteinian dream of a complete geometrization of the interactions is reached.
The results achieved in the present work have allowed to design, build, and test of devices capable of exploiting the behavior of the fifth element of the metrics to obtain the production of electric charges directly from the nuclear metamorphosis of the matter.
Downloads
Article Details
Copyright (c) 2024 Benenti S, et al.
This work is licensed under a Creative Commons Attribution 4.0 International License.
Cardone F, Mignani R. Deformed Spacetime. Fundamental Theories of Physics. 2007; 157.
Carroll SM. Lectures Notes on General Relativity. ArXiv 1997.
Albertini G, Calbucci V, Cardone F, Fattorini G, Mignani R, Petrucci A, Ridolfi F, Rotili A. Evidence of Alpha Emission from Compressed Steel Bars. International Journal of Modern Physics B. World Scientific Publishing Company 2013; 27.
Cardone F, Calbucci V, Albertini G. Possible Evidence of Piezonuclear Alpha Emission. Journal of Advanced Physics. American Scientific Publishers. 2013; 2.
Cardone F, Calbucci V, Albertini G. Deformed Space-Time of the Piezonuclear Emissions, Modern Physics Letters B. 2014; 28.
Cardone F, Albertini G, Bassani D, Cherubini G, Guerriero E, Mignani R, Monti M, Petrucci A, Ridolfi F, Rosada A, Rosetto F, Sala V, Santoro E, Spera G. Nuclear metamorphosis in mercury. International Journal of Modern Physics B. 2016; 30.
Cardone F, Albertini G, Bassani D, Cherubini G, Guerriero E, Mignani R, Monti M, Petrucci A, Ridolfi F, Rosada A, Rosetto F, Sala V, Santoro E, Spera G. Deformed Space-Time Transformations in Mercury. International Journal of Modern Physics B. World Scientific Publishing Company. 2017; 31.
Albertini G, Cardone F, Cherubini G, Guerriero E, Rosada A. Reduction of the Radiation in Radioactive Substances. International Journal of Modern Physics B. World Scientific Publishing Company. 2020; 34.
Rosada A, Cardone F, Avino P. The Astonishing 63 Ni Radioactivity Reduction in Radioactive Wastes by Means of Ultrasounds Application. Springer Nature Applied Sciences. 2019; 1319.
Cardone F, Albertini G, Bassani D, Cherubini G, Petrucci A. Rosada A. DST-deactivation of Nickel-63 Nitrate. Radiochimica Acta. 2019; 107.
Albertini G, Bassani D, Cardone F, Cherubini G, Guerriero E, Rosada A. Neutralization of radionuclides, International Journal of Modern Physics B. World Scientific Publishing Company. 2021; 35.
Kostro L, Lange P. Physick Essays. 1999; 10.
Cardone F, Mignani R. Energy and Geometry, World Scientific. 2004.
Benenti S. Mathematical Foundations and Numerical Analysis of the Dynamics of an Isotropic Universe, Memoirs of the Academy of Sciences of Turin, Class of S.F.M.N. 2018-2019; 42-43.
de La Place PSM. Celestial Mechanics, Traslated with a Commentary by N. Bodwitch, Boston, 1829.
Cardone F, Perconti W, Laposta C. Cosmic Microwave Background Radiation Preferred Directions and Asymmetry in Lorentz Violation. Journal of Advanced Physics. 2015; 4:1-5.
Cardone F, Perconti W, Petrucci A. Deformed Space-Time Asymmetric Emissions and Cosmic Microwave Background Radiation Preferred Directions. Journal of Advanced Physics. 2016; 6: 1-5.
Cardone F, Perconti W, Petrucci A, Violation L. Cosmic Microwave Background Radiation Anisotropy and Critical Energy Density of the Universe. Journal of Advanced Physics. 2018; 7: 1–7.
Albertini G, Cardone F, Bellucci S. The Asymmetry of the Cosmic Microwave Background Radiation as Signature of Local Lorentz Invariance Violation, Advances in High Energy Physics. 2022; 6271119. 10. https://doi.org/10.1155/2022/6271119.
Cardone F, Albertini G, Bassani D. Lorentz Violation in Torsional Antenna. Foundations of Science. 2022; 27:43-55. https://doi.org/10.1007/s10699-020-09710-z.
Albertini G, Bassani D. Deformed Space-Time Reactions and Their Phenomenology. Physics Journal. 2015; 1: . 382–387.
Eisenhart LP. Riemannian Geometry, Princeton University Press. 1925.
Eisenhart LP. Non-Riemannian Geometry. Am Math Society. 1949.
Hamilton RS. Three-manifolds with positive Ricci curvature. Differential Geometry. 1982;17: 255-306.
Cao HD, Zhu XP. A complete proof of the Poincar and geometrization conjectures – Application of the Hamilton-Perelman theory of the Ricci flow. Asian J Math. International Press. 2006; 10; 165-492.
Wald RM. General Relativity. University Chicago Press. 1984.
Misner CW, Thorne KS, Wheeler JA. Gravitation. WH. Freeman & Company. 1973.