Dirac Type Gauge Theories and the Mass of the Higgs Boson

TL;DR

This paper predicts the Higgs boson mass using a Dirac type gauge theory approach to the Standard Model, providing a specific value that aligns with experimental bounds and exploring implications of neutrino masses and non-commutative geometry.

Contribution

It introduces a Dirac type gauge theory formulation of the Standard Model that yields a definite Higgs mass prediction, contrasting with the usual approach.

Findings

Predicted Higgs mass around 184-186 GeV depending on top mass.

The predicted Higgs mass aligns with the Standard Model's allowed range.

Inclusion of neutrino masses does not change the results.

Abstract

We discuss the mass of the (physical component of the) Higgs boson in one-loop and top-quark mass approximation. For this the minimal Standard Model is regarded as a specific (parameterized) gauge theory of Dirac type. It is shown that the latter formulation, in contrast to the usual description of the Standard Model, gives a definite value for the Higgs mass. The predicted value for the Higgs mass depends on the value addressed to the top mass m_T. We obtain m_H= 186 \pm 8 GeV for m_T = 174 \pm 3 GeV (direct observation of top events), resp. m_H = 184 \pm 22 GeV for m_T = 172 \pm 10 GeV (Standard Model electroweak fit). Although the Higgs mass is predicted to be near the upper bound, m_H is in full accordance with the range 114 \leq m_H < 193 GeV that is allowed by the Standard Model. We show that the inclusion of (Dirac) massive neutrinos does not alter the results presented. We also briefly discuss how the derived mass values are related to those obtained within the frame of non-commutative geometry.