Three-band extension for the Glashow-Weinberg-Salam model

Abstract

By analogy with the Ginzburg-Landau theory of multi-band superconductors with inner (interband) Josephson couplings we formulate the three-band Glashow-Weinberg-Salam model with weak Josephson couplings between strongly asymmetrical condensates of scalar (Higgs) fields. Unlike usual single-band model, we found three Higgs bosons corresponding to three generations of particles, moreover the heaviest of them corresponds to the already discovered H-boson and decays into fermions of only the third generation through Yukawa interaction. The other two decay into fermions of the first and second generations accordingly, but they are difficult to observe due to very poor conditions for production. We found two sterile ultra-light Leggett bosons, the Bose condensates of which form the dark halos of galaxies and their clusters (i.e so called "dark matter"). The masses of the Leggett bosons are determined by the coefficient of the interband coupling and can be arbitrarily small ( 10-20eV) due to non-perturbativeness of the interband coupling. Since propagation of Leggett bosons is not accompanied by current, these bosons are not absorbed by gauge fields unlike the common-mode Goldstone bosons. Three coupled condensates of the scalar fields are related to the existence of three generations of leptons, where each generation interacts with the corresponding condensate getting mass. The interflavour mixing between the generations of active neutrinos and sterile right-handed neutrinos in the three-band system causes the existence of mass states of neutrino without interaction with the Higgs condensates.