WEYL INVARIANT STANDARD MODEL AND ITS SYMMETRY BREAKING

Abstract

A standard model is formulated in a Weyl space, W4, yielding a Weyl covariant dynamics of massless chiral Dirac fermion fields for leptons and quarks as well as the gauge fields involved for the groups D(1) (Weyl), U(1)Y × SU (2)W (electroweak), SU (3)c (color), SO(3, 1) (gravity) and SO(4, 1) (strong interaction, symmetry breaking). The dynamics is based on a gauge and Weyl invariant Lagrangian density [Formula: see text]. Gravitation is included from the beginning as the gauge aspect of the Lorentz group which is here extended in the hadronic sector of the model to the ten-parameter SO(4, 1) de Sitter group. A part of the dynamics is, as usual, a scalar isospinor field ϕ being a section on a bundle related to the electroweak gauge group and to symmetry breaking. In parallel to ϕ on the leptonic side a section [Formula: see text] on the hadronic side is considered as part of the dynamics, governing the symmetry breaking SO(4, 1) → SO(3, 1) and recovering gravitation in the symmetry breaking limit outside the regions in space–time where strong interactions persist. Besides spin, isospin and helicity the Weyl weights determine the form of the contributions of fields in [Formula: see text]. Of particular interest is the appearance of a current–current self-interaction of quark fields allowed by the Weyl weight changing the debate about quark masses. In a second step the D(1)-Weyl symmetry is explicitly broken and a universal mass scale is established through the mass of the ϕ-field appearing in the symmetry breaking Lagrangian [Formula: see text]. The Weyl symmetry breaking is governed by the relation DμΦ2 = 0, where Φ is the norm of ϕ. After D(1) symmetry breaking the masses of the weak bosons and of the electron appear on the scene through the energy–momentum tensor of the ϕ-field.