Subluminal and Superluminal Electromagnetic Waves and the Lepton Mass Spectrum

Abstract

Maxwell equation F = 0 for F ∈ 2 M ⊂ (M), where (M) is the Clifford bundle of differential forms, have subluminal and superluminal solutions characterized by F2 ≠ 0. We can write F = γ21 where ∈ +(M). We can show that satisfies a non linear Dirac-Hestenes Equation (NLDHE). Under reasonable assumptions we can reduce the NLDHE to the linear Dirac-Hestenes Equation (DHE). This happens for constant values of the Takabayasi angle (0 or π). The massless Dirac equation =0, ∈ + (M), is equivalent to a generalized Maxwell equation F = Je - γ5 Jm = J. For = a positive parity eigenstate, je = 0. Calling e the solution corresponding to the electron, coming from Fe =0, we show that the NLDHE for such that γ21 = Fe + F gives a linear DHE for Takabayasi angles π/2 and 3π/2 with the muon mass. The Tau mass can also be obtained with additional hypothesis.

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