Through a phenomenological approach using the concept of sub-quantum fluid, the theory argues the possibility of a cold genesis of elementary particles and of fields, explaining the electro-magnetic and the gravitic fields by equations of ideal fluids applied to the subquantum and the quantum “primordial dark energy”. The possibility to explain the cold genesis of “dark” photons and of “dark” elementary particles is obtained by a CF -chiral soliton model of lepton, resulted as vortex of „primordial dark energy”, respective- as Bose-Einstein condensate of gammonic (e+-e-)-pairs confined in a very strong magnetic field, in the Protouniverse’s period of time. This possibility results by a model of primordial ‘gravistar’ with a self-growing property given by the confining of “primordial dark energy” into “dark photons” and into “dark particles” by a “vortex cascade” mechanism induced by its magnetic field and gravitationally sustained. The supposed primordial “big bang” of the Universe results as a period of gravistars transforming into magnetars, supernovae and into (micro) quasars. The resulted model of expanding Universe gives a semi-sinusoidal variation of the expansion speed. The approach, even if does not propose an enough unitary equation of the known basic fields, it explains naturally the fundamental interactions, by the same basic concept.
| Published in |
International Journal of High Energy Physics (Volume 2, Issue 4-1)
This article belongs to the Special Issue Symmetries in Relativity, Quantum Theory, and Unified Theories |
| DOI | 10.11648/j.ijhep.s.2015020401.17 |
| Page(s) | 80-103 |
| Creative Commons |
This is an Open Access article, distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution and reproduction in any medium or format, provided the original work is properly cited. |
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Copyright © The Author(s), 2024. Published by Science Publishing Group |
Unitary Theory, Gravistar, Chiral Soliton, Dark Energy, Dark Matter, CF-Particles, Bosons Confining, Expanding Universe
| [1] | M.Arghirescu - ‘The Cold Genesis of Matter and Fields’, Science Publishing Group, (2015). |
| [2] | T.H.R. Skyrme, Proc. Roy. Soc. Series A260 (1961) 127 G.S. Adkins, ‘Chiral Soliton ‘, ed. by G.S. Adkins, Add. - Wesley, (1988); O.L. Battistel, Doctoral thesis, Instituto de Fısica da Universidad de Sao Paulo, Brazil, (1994). |
| [3] | E. Mottola, P.O. Mazur‚‚Gravitational Condensate stars: An Alternative to Black Holes’ arXiv: gr-qc/ 0109035 (2001). |
| [4] | I. Şomăcescu - ‘L’éléctromagnetisme et la gravitoinertie en une theorie unitaire’ International Conf. of Gravitation, G.R.11, Abstract Book, Stockholm, 27 feb. (1986); E.M. Kelly -‘Vacuum electromagnetic derived from the properties of an ideal fluid’, Nuovo Cimento, 11, 32B, March (1976). |
| [5] | Georges L. Lesage-‘Lucrece newtonien’, Memoires de l’Academie royale des sciences et belles lettres de Berlin, Berlin (1784) 1-28. |
| [6] | R. P. Lano- ‚Gravitational Meissner Effect’, arXiv: hep-th/9603077 (1996); N. I. Pallas, L. Sofonea- Book of International Congres of Mathematicians, Helsinki (1978). |
| [7] | M. Agop, C. Gh. Buzea, B. Ciobanu - ‚On Gravitational Shielding in Electromagnetic Fields’, arXiv: physics/9911011 (1999); |
| [8] | Hector A. Munera - ‘A semiclassical Model of the Photon based on Objective Reality and Containing Longitudinal Field Components’, Myron W. Evans- „Modern Nonlinear Optics”, Ed. John Wiley&Sons Inc., (2002) 335-385. |
| [9] | G. Hunter, R. L. P. Wadlinger - ‘Photons and Neutrinos as Electromagnetic Solitons’, Physics Essays, Vol. 2 (1989) 158-172. |
| [10] | R. M. Kiehn - ‘The Falaco Effect, A Topological Soliton’, Talk at 1987 Dynamics Days, Austin, Texas, jan. (1987); R.M. Kiehn-’Coherent Structures in Fluids are Deformable Topological Torsion Defects’, IUTAM-SIMFLO Conference at DTU, Denmark, May 25-29, (1997) |
| [11] | G. Hunter, L.P. Wadlinger et. al, ‚Gravitation and Cosmology: From the Hubble Radius to the Planck Scale’, „Fundamental Theories of Physics”, Vol. 126, (2002), pp 157-166. |
| [12] | Weinberger, P., Philosophical Magazine Letters 88 (12), (2008) 897–907. |
| [13] | A. Cotton, H. Mouton, Ct. r. hebd. Seanc. Acad. Sci. Paris 141, (1905) 317- 349. |
| [14] | R. D. Chipman, L. D. Jennings, Phys. Rev. 132 (1995) 728; Greenberg, O. W., Yodh, G. B., Phys. Rev. Lett., 32 (1974) 1473. |
| [15] | K. N. Muhin – ‚Experimental Nuclear Physics’, Vol. 1-2, Ed.“Atomizdat”, Moscow (1974). |
| [16] | I. Sick - ‘On the rms-radius of Proton’, Phys. Lett., B 576 (2003) 62-63. |
| [17] | G. Adkins, C. Nappi, E. Witten - ‚Static properties of nucleons in the Skyrme model’, Nucl. Phys., B228 (1983) 552-566. |
| [18] | P. Constantinescu, „Hierarchized Systems”, Ed. Acad. R. S. R., Bucharest (1986) 106. |
| [19] | V. P. Oleinik - ‘Nonlinear QDE for Self-acting Electron’, Nonlinear Math. - Phys. Rev., v.4, No1-2 (1997) 180. |
| [20] | W. Peschka- ‚Kinetobaric Effect as possible Basis for a New Propulsion Principle’, Raumfahrforschung, no 18 (1974). |
| [21] | D. L. Burke et al., ‚Positron production in multiphoton light - by light scattering’, Phys. Rev. Letters 79 (1997) 1626-1629; Physics Today 51, Feb. (1998) 17-18. |
| [22] | M. Brunetti et al., ‚Gamma-ray bursts of atmospheric origin in the MeV energy range’ Geophys. Research Letters 27, 1 (2000) 1595. |
| [23] | R. Jastrow-Phys. Review, 81 (1951) 165. |
| [24] | Y. Yan, R. Tegen- ‚N-N Scattering and Nucleon Quark core’, Science Asia, 27 (2001) 251. |
| [25] | Patent: US2482773. |
| [26] | Dan Rădulescu - Bulletin de la Société des Sciences, Cluj (1922). |
| [27] | The OPERA Collaboration (2011), ‚Measurement of the neutrino velocity with the OPERA detector in the CNGS beam’, ar Xiv: 1109.4897v1. |
| [28] | L. Wolfenstein- Phys. Lett., B 107 (1981) 77. |
| [29] | Shull Michael, Stern Alan, Astronomical Journ., Vol. 109, No2 (1995) 690-697. |
| [30] | Science et Avenir, No. 555, may (1993). |
| [31] | B. Rossi, D. B. Hall - Phys. Rev., 59 (1941) 223. |
| [32] | T. Schmidt, Z. Phys., 106 (1937) 358. |
| [33] | T. Lonnroth, Il Nuovo Cimento 110A (1997) 961. |
| [34] | W. Bauer, Proc. of 1st Catania Relativistic Ion Studies, Asicastello, Italy (1996) 23. |
| [35] | A. Săndulescu et. al - Nucl. Physics., 48 (1963) 345. |
| [36] | Shaw P. E., Davy N., Phys. Rev., Vol. 21, Ser. 2, Iss. 6 (1923) 680-681. |
| [37] | J. Kristian, A. Sandage, J. Westphal - Astrophys. Journal, 221 (1978) 383. |
| [38] | W. L. Freedman et al., Astrophys. J. 704 (2009) 1036; arXiv: 0907.4524. |
| [39] | C. F. C. Brandt, R. Chan, M. F. A. da Silva, P. Rocha, ‚Gravastar with an Interior Dark Energy Fluid and an Exterior de Sitter-Schwarzschild Spacetime’, arXiv: gr-qc/1012.1233v1 (2010). |
| [40] | Pietronero, L. ‚The Fractal Structure of the Universe: Correlations of Galaxies and Clusters’, Physica A (144): 257, (1987). |
| [41] | C. Kouveliotou, R. C. Duncan, C. Thompson, ‘Magnetars’, Scientific American Rev., Febr. (2003) 237. |
| [42] | I. F. Mirabel- ‚Microquasars as sources of high energy phenomena’ arXiv: astro-ph/0211085 v1, 5 Nov. (2002). |
| [43] | ‘Scientific American’, January, (1999) |
| [44] | Polnarev, A. G., Khlopov, M. Y. – ,Primordial Black Holes and the Era of Superheavy Particle Dominance in the Early Universe, Soviet Astronomy Journ., V.25 (1981) 406. |
| [45] | O.B. Zaslavskii, „Acceleration of particles as universal property of rotating black holes”, arXiv: 1007.3678v2 [gr-qc] 15 oct. 2010; O.B. Zaslavskii, „Acceleration of particles as universal property of rotating black holes”, arXiv: 1007.3678v2 [gr-qc] 15 oct. 2010 |
| [46] | Thomsen, D. E.- ‚End of the World: You Won't Feel a Thing’, Science News (Society for Science & the Public), Jun 20, (1987), 131 (25):391, |
| [47] | Tingting Liu et al., ‚A Periodically varying Luminous Quasar at z = 2 from the Pan-Starrs1, Medium Deep Survey: A Candidate Supermassive Black Hole Binary in the Gravitational wave-Driven regime’, arXiv:1503.02083v1 [astro-ph. HE] |
| [48] | Irene, K.-‚Surprise Quasar Quartet Defies Explanation’, news.discovery.com., 14 may, (2015) |
| [49] | S. A. Colgate & R. H. White- ‚The Hydrodynamic Behavior of Supernova Explosions’, The Astrophysical Journal, 143 (1966) 626 ; doi:10.1086/148549 |
| [50] | A.K. Mann (1997) Shadow of a star: The neutrino story of Supernova 1987A. W. H. Freeman. p. 122.ISBN 0-7167-3097-9 |
| [51] | Metzger, B. et al.- ‚Proto-Neutron Star Winds, Magnetar Birth, and Gamma-Ray Bursts’. AIP Conference Proceedings „SUPERNOVA 1987A: 20 YEARS AFTER”, 937, (2007), pp. 521–525. |
| [52] | L. Nottale‚ Scale Relativity and Fractal Space-Time: Applications to Quantum Physics, Cosmology and Chaotic Systems’, Chaos, Solitons& Fractals, Vol.7, No.6 (1996) 887-938. |
| [53] | Klaers, J., Schmitt, J., Vewinger, F., Weitz, M., Nature, 468, 546-548 (2010); Zeeya Merali, ‚Chilled light enters a new phase’, Nature, 24 Nov. (2010). |
| [54] | Heinze, G., Hubrich, C., Halfmann T., ‚Stopped Light and Image Storage by Electromagnetically Induced Transparency up to the Regime of One Minute’, Phys. Rev. Lett. 111, 038103 (2013); |
| [55] | L. V. Hau, S. E. Harris, Z. Dutton, C. H. Behroozi, “Ultra-slow, stopped, and compressed light in Bose-Einstein condensates gas”, Nature 397, 594, (1999); S. E. Harris and L. V. Hau, Phys. Rev. Lett. 82, 4611 (1999). |
APA Style
Marius Arghirescu. (2015). A Quasi-Unitary Pre-Quantum Theory of Particles and Fields and Some Theoretical Implications. International Journal of High Energy Physics, 2(4-1), 80-103. https://doi.org/10.11648/j.ijhep.s.2015020401.17
ACS Style
Marius Arghirescu. A Quasi-Unitary Pre-Quantum Theory of Particles and Fields and Some Theoretical Implications. Int. J. High Energy Phys. 2015, 2(4-1), 80-103. doi: 10.11648/j.ijhep.s.2015020401.17
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Download@article{10.11648/j.ijhep.s.2015020401.17,
author = {Marius Arghirescu},
title = {A Quasi-Unitary Pre-Quantum Theory of Particles and Fields and Some Theoretical Implications},
journal = {International Journal of High Energy Physics},
volume = {2},
number = {4-1},
pages = {80-103},
doi = {10.11648/j.ijhep.s.2015020401.17},
url = {https://doi.org/10.11648/j.ijhep.s.2015020401.17},
eprint = {https://article.sciencepublishinggroup.com/pdf/10.11648.j.ijhep.s.2015020401.17},
abstract = {Through a phenomenological approach using the concept of sub-quantum fluid, the theory argues the possibility of a cold genesis of elementary particles and of fields, explaining the electro-magnetic and the gravitic fields by equations of ideal fluids applied to the subquantum and the quantum “primordial dark energy”. The possibility to explain the cold genesis of “dark” photons and of “dark” elementary particles is obtained by a CF -chiral soliton model of lepton, resulted as vortex of „primordial dark energy”, respective- as Bose-Einstein condensate of gammonic (e+-e-)-pairs confined in a very strong magnetic field, in the Protouniverse’s period of time. This possibility results by a model of primordial ‘gravistar’ with a self-growing property given by the confining of “primordial dark energy” into “dark photons” and into “dark particles” by a “vortex cascade” mechanism induced by its magnetic field and gravitationally sustained. The supposed primordial “big bang” of the Universe results as a period of gravistars transforming into magnetars, supernovae and into (micro) quasars. The resulted model of expanding Universe gives a semi-sinusoidal variation of the expansion speed. The approach, even if does not propose an enough unitary equation of the known basic fields, it explains naturally the fundamental interactions, by the same basic concept.},
year = {2015}
}
TY - JOUR T1 - A Quasi-Unitary Pre-Quantum Theory of Particles and Fields and Some Theoretical Implications AU - Marius Arghirescu Y1 - 2015/07/23 PY - 2015 N1 - https://doi.org/10.11648/j.ijhep.s.2015020401.17 DO - 10.11648/j.ijhep.s.2015020401.17 T2 - International Journal of High Energy Physics JF - International Journal of High Energy Physics JO - International Journal of High Energy Physics SP - 80 EP - 103 PB - Science Publishing Group SN - 2376-7448 UR - https://doi.org/10.11648/j.ijhep.s.2015020401.17 AB - Through a phenomenological approach using the concept of sub-quantum fluid, the theory argues the possibility of a cold genesis of elementary particles and of fields, explaining the electro-magnetic and the gravitic fields by equations of ideal fluids applied to the subquantum and the quantum “primordial dark energy”. The possibility to explain the cold genesis of “dark” photons and of “dark” elementary particles is obtained by a CF -chiral soliton model of lepton, resulted as vortex of „primordial dark energy”, respective- as Bose-Einstein condensate of gammonic (e+-e-)-pairs confined in a very strong magnetic field, in the Protouniverse’s period of time. This possibility results by a model of primordial ‘gravistar’ with a self-growing property given by the confining of “primordial dark energy” into “dark photons” and into “dark particles” by a “vortex cascade” mechanism induced by its magnetic field and gravitationally sustained. The supposed primordial “big bang” of the Universe results as a period of gravistars transforming into magnetars, supernovae and into (micro) quasars. The resulted model of expanding Universe gives a semi-sinusoidal variation of the expansion speed. The approach, even if does not propose an enough unitary equation of the known basic fields, it explains naturally the fundamental interactions, by the same basic concept. VL - 2 IS - 4-1 ER -
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