The problem of weak and strong nuclear forces and prediction of the Higgs-Boson mass from the GEMS (Gravity electromagnetism strong) unification theory

Original Article

John Brandenburg

Abstract

The GEMS (Gravity Electro-Magnetism Strong) theory is extended to the problem of Weak and Strong Nuclear Forces and the problem of the Higgs Boson mass, as the beginning of an effort to include short range Nuclear Forces in the successful GEM unification theory. The presence of a compact 5th dimension is found to create subatomic structures upon which surface resonances and Mie scatterings occur, and these resonances can give rise quanta, called, here, mieons, that mediate nuclear forces.. In the Kaluza-Klein theory of EM and gravity, a 5th force field called the “Radion” arises as a scalar, with a signature number of the Radion interaction in the GEM theory: =42.8503. Higher order resonances off the electrostatic radii of the electron, proton and 5th dimension size form of the GEM theory, generate the quanta with masses of the pion m = 2 me / 140.0 MeV and Z boson: mZ =2 mp = 80.4 GeV. The c meson m =2985 GeV is identified with the 5th dimension compactification force mediated by the Radion field. Another particle associated with is the Radion scattering quanta off the fifth dimension with a mass m  127.7 GeV, which is the Higgs-Boson.

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