Electroweak SU(2)L × U(1)Y model with strong spontaneously fermion-mass-generating gauge dynamics

Abstract

Higgs sector of the Standard model (SM) is replaced by quantum flavor dynamics (QFD), the gauged flavor SU(3)f symmetry with scale . Anomaly freedom requires addition of three R. The approximate QFD Schwinger-Dyson equation for the Euclidean infrared fermion self-energies f(p2) has the spontaneous-chiral-symmetry-breaking solutions ideal for seesaw: (1) f(p2)=MfR2/p where three Majorana masses MfR of fR are of order . (2) f(p2)=mf2/p where three Dirac masses mf=m(0)1+m(3)λ3+m(8)λ8 of SM fermions are exponentially suppressed w.r.t. , and degenerate for all SM fermions in f. (1) MfR break SU(3)f symmetry completely; m(3),m(8) superimpose the tiny breaking to U(1) × U(1). All flavor gluons thus acquire self-consistently the masses . (2) All mf break the electroweak SU(2)L × U(1)Y to U(1)em. Symmetry partners of the composite Nambu-Goldstone bosons are the genuine Higgs particles: (1) Three R-composed Higgses i with masses . (2) Two new SM-fermion-composed Higgses h3, h8 with masses m(3), m(8), respectively. (3) The SM-like SM-fermion-composed Higgs h with mass m(0), the effective Fermi scale. f(p2)-dependent vertices in the electroweak Ward-Takahashi identities imply: The axial-vector ones give rise to the W and Z masses at Fermi scale. The polar-vector ones give rise to the fermion mass splitting in f. At the present exploratory stage the splitting comes out unrealistic.