High Energy Particle Physics

   

Theory of Fermion Masses, Mixing Angles, Lagrangian Potentials and Beta Decays, Based on Higgs Bosons Arising from the Scaler Fields of a Kaluza Klein Theory Given Five-Dimensional General Covariance by Dirac’s Quantum Theory of the Electron

Authors: Jay R. Yablon

Why the twelve elementary fermions have the masses they have, (and what the neutrino masses actually are) is one of the deepest unsolved mysteries of modern physics. We crack this puzzle using a theory of fermion masses which succeeds in reparameterizing all twelve fermion masses in terms of other known parameters for which the theoretical interconnection to these masses have not heretofore been understood. The first step is to “repair” long-recognized perplexities of Kaluza-Klein theory using Dirac’s quantum theory of the electron to enforce general covariance across all five dimensions. One consequence of this is the emergence of a modified Dirac equation for fermions which naturally contains the Kaluza-Klein scaler. After establishing a connection between this Kaluza-Klein scaler and the standard model Higgs scaler, we use the latter to connect the known masses of all the quarks and charged leptons to the CKM and PMNS mixing angles and several other parameters which have heretofore not been theoretically connected to these masses. Then, after using the Newton gravitational constant and the Fermi vacuum to establish a sum of neutrino masses in the exact range expected from experiments, it also becomes possible to predict the rest masses of the three neutrinos. Also predicted are the existence and rest mass of a second leptonic Higgs boson, and tighter values for several other known parameters including the mass of the established Higgs boson. Also uncovered is a new, deep role for the cosmological neutrino background (CvB) and the Higgs boson in triggering and facilitating weak interaction beta decay events.

Comments: 162 Pages.

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Submission history

[v1] 2018-11-07 14:43:27

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