$W$ boson mass in gauge-Higgs unification

TL;DR

This paper calculates the W boson mass within a gauge-Higgs unification model in warped space, accounting for Kaluza-Klein modes and space curvature, and compares predictions with experimental values including recent CDF results.

Contribution

It provides a detailed prediction of the W boson mass in a specific gauge-Higgs unification framework, incorporating effects of extra dimensions and KK modes, and constrains model parameters based on experimental data.

Findings

Predicted W boson mass range aligns between SM and CDF measurements.

Constraints on the Aharonov-Bohm phase $ heta_H$ for given KK mass scale.

Model accommodates recent experimental W mass measurements.

Abstract

The $W$ boson mass $m_W$ in the GUT inspired $SO(5) \times U(1) \times SU(3)$ gauge-Higgs unification in the Randall-Sundrum (RS) warped space is evaluated. The muon decay $\mu^- \rightarrow e^- \bar{\nu}_e \nu_\mu$ proceeds by the exchange of not only the zero mode of the $W$ boson $(W^{(0)}$) but also Kaluza-Klein (KK) excited modes $W^{(n)}$ and $W_R^{(n)}$ ($n \ge 1$) at the tree level. The anti-de Sitter curvature of the RS space also affects the relationship among the gauge couplings and the ratio of $m_W$ to the $Z$ boson mass $m_Z$. The $W$ couplings of leptons and quarks also change. With the given KK mass scale $m_{\rm KK}$ the range of the Aharonov-Bohm phase $\theta_H$ in the fifth dimension is constrained. For $m_{\rm KK} = 13\,$TeV, $0.085 \lesssim \theta_H \lesssim 0.11$ and $80.381\,{\rm GeV} \lesssim m_W \lesssim 80.407\,{\rm GeV}$. The predicted value of $m_W$ for $13\, {\rm TeV} \le m_{\rm KK} \le 20\, {\rm TeV}$ lies between $m_W^{\rm SM} = 80.354 \pm 0.007\,$GeV in the standard model and $m_W^{\rm CDF} = 80.4335 \pm 0.0094\,$GeV, the value reported by the CDF collaboration in 2022.