The weak bound state with the non-zero charge density as the LHC 126.5 GeV state

TL;DR

This paper proposes a classical field model that predicts a weakly charged, weakly bound state with a mass around 126.5 GeV, potentially corresponding to the Higgs boson observed at the LHC.

Contribution

It introduces a self-consistent classical field approach to electroweak configurations, identifying solutions with masses matching the LHC Higgs boson, offering a novel interpretation of its nature.

Findings

Identified solutions with masses near 126.67 GeV and 123.7 GeV.

Proposed a neutral droplet as a decay product of a charged configuration.

Linked the neutral droplet to the 126.5 GeV state observed at LHC.

Abstract

The self-consistent model of classical field interactions formulated as the counterpart of the quantum electroweak model leads to homogeneous boson ground state solutions in presence of non-zero extended fermionic charge density fluctuations. Two different types of electroweak configurations of fields are analyzed. The first one has non-zero electric and weak charge fluctuations. The second one is electrically uncharged but weakly charged. Both types of configurations have two physically interesting solutions which possess masses equal to 126.67 GeV at the value of the scalar fluctuation potential parameter $\lambda$ equal to ~ 0.0652. The spin zero electrically uncharged droplet formed as a result of the decay of the charged one is interpreted as the ~ 126.5 GeV state found in the Large Hadron Collider (LHC) experiment. (The other two configurations correspond to solutions with masses equal to 123.7 GeV and $\lambda$ equal to ~ 0.0498 and thus the algebraic mean of the masses of two central solutions, i.e., 126.67 GeV and 123.7 GeV, is equal to 125.185 GeV.) The problem of a mass of this kind of droplets will be considered on the basis of the phenomenon of the screening of the fluctuation of charges. Their masses are found in the thin wall approximation.