| viXra.org > High Energy Particle Physics > 2410 |
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| viXra.org > High Energy Particle Physics > 2410 |
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[4] viXra:2410.0182 [pdf] submitted on 2024-10-30 10:25:44
Authors: Rainer W. Kühne
Comments: 4 Pages.
Textbooks tell us that the coupling constant of Dirac magnetic monopoles is 34.259. Here I show by using the quark hypothesis that at zero temperature the coupling constant is as high as 308.331. Moreover I show that it is a running coupling constant and is smaller than 0.5 at the Planck temperature.
Category: High Energy Particle Physics
[3] viXra:2410.0171 [pdf] submitted on 2024-10-29 02:41:27
Authors: Mykola Kosinov
Comments: 6 Pages.
The article explores the relationship between the masses of elementary particles and the fine-structure constant α. In addition to the Koide formula, a new formula is proposed, which is as accurate as the Koide formula. The new formula demonstrates the connection between the masses of four elementary particles (electron, proton, tau lepton, and muon) with the fine-structure constant α: Considering the high precision of the fine-structure constant and the accurate experimental values of the electron, proton, and muon masses, the new formula provides a significantly more accurate value for the mass of the tau lepton compared to the current experimental value:mτ/me=3477.0298u2026 (1776.7586u2026 MeV)The obtained value of the tau lepton mass (1776.7586... MeV/c2) is within the range of the experimental value but does not coincide with the result obtained by the Koide formula (1776.9688... MeV/c2). The Koide formula and the new formula yield different values for the mass of the tau lepton with high precision in both results. Both mass values are significantly more accurate than the current experimental value. The discrepancy between the results of the two formulas requires explanation.
Category: High Energy Particle Physics
[2] viXra:2410.0150 [pdf] submitted on 2024-10-24 20:44:40
Authors: Bittu Kumar
Comments: 10 Pages.
This research redefines gravity, showing that it is not a separate force but originates from atoms, specifically from the nucleus of the atom. Rather than arising from space-time curvature or the hypothetical graviton particle, this theory suggests that gravity is positive force of atom, that exhibits a weak attraction to neutral atoms (neutral objects) and repel same charge atom (positive charge objects). Moreover, utilizing the framework of gravity, this paper provides a practical and detailed explanation of how the solar system, galaxy, and the broader universe operate. This model solves key cosmological problems, presenting a more tangible and applicable understanding of cosmic phenomena, as opposed to purely theoretical and hypothetical approaches, and combines quantum mechanics and classical physics with gravity.
Category: High Energy Particle Physics
[1] viXra:2410.0009 [pdf] submitted on 2024-10-03 23:37:25
Authors: Gang Chen, Tianman Chen, Tianyi Chen
Comments: 9 Pages. 1 Figures.
In our previous papers, we constructed a model for the masses of elementary particles and calculated the masses of elementary particles especially in atomic units. In this paper, based on the recent more accurate measurements of the masses of the W boson, the Z boson and the Higgs bosons, we revise our previous calculations and give news values of their masses which are 157248.297520661, 178449.921111111 and 244920.803503690 in atomic units, or 80353.714694 (24) MeV, 91187.722057(27) MeV and 125154.273069(26) MeV respectively. Compared to the latest and most accurate measured values of the masses of the W boson, the Z boson and the Higgs bosons which are 80360.2(9.9) MeV, 91187.6(2.1) MeV and 125.11(11) GeV respectively, our new calculated values are very precise if they are correct.
Category: High Energy Particle Physics
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