Bogoliubov compensation principle in the electro-weak interaction: value of the gauge constant, muon g-2 anomaly, predictions for Tevatron and LHC

TL;DR

This paper uses the Bogoliubov compensation principle to derive an anomalous gauge interaction in the electroweak sector, explaining the muon g-2 anomaly and predicting effects for Tevatron and LHC experiments.

Contribution

It introduces a spontaneous generation of an anomalous three-boson gauge interaction in the electroweak theory, determining key parameters and explaining experimental anomalies.

Findings

Observable electroweak coupling value in agreement with experiment

Natural explanation for muon g-2 discrepancy

Predictions for collider experiments at Tevatron and LHC

Abstract

We apply Bogoliubov compensation principle to the gauge electro-weak interaction to demonstrate a spontaneous generation of anomalous three-boson gauge invariant effective interaction. The non-trivial solution of compensation equations uniquely defines values of parameters of the theory and the form-factor of the anomalous interaction. The contribution of this interaction to running EW coupling $\alpha_{ew}(p^2)$ gives its observable value $\alpha_{ew}(M_W^2)=0.0374$ in satisfactory agreement to the experiment. The anomalous three-boson interaction gives natural explanation of the well-known discrepancy in muon $g-2$. The implications for EW studies at Tevatron and LHC are briefly discussed.