Generalised CP and $A_4$ Family Symmetry

TL;DR

This paper explores how combining $A_4$ family symmetry with generalized CP symmetry constrains lepton mixing, leading to specific predictions for CP violation and neutrino masses, with a focus on phenomenologically viable models.

Contribution

It identifies the unique viable symmetry breaking pattern in $A_4$ and generalized CP models, and constructs an effective supersymmetric model with sharp neutrino mass and CP phase predictions.

Findings

Only one symmetry breaking case is phenomenologically viable.

The model predicts either no CP violation or maximal CP violation in neutrinos.

Neutrino masses depend on only three real parameters, with maximal atmospheric mixing.

Abstract

We perform a comprehensive study of family symmetry models based on $A_4$ combined with the generalised CP symmetry $H_{\rm{CP}}$. We investigate the lepton mixing parameters which can be obtained from the original symmetry $A_4\rtimes H_{\rm{CP}}$ breaking to different remnant symmetries in the neutrino and charged lepton sectors. We find that only one case is phenomenologically viable, namely $G^{\nu}_{\rm{CP}}\cong Z^{S}_2\times H^{\nu}_{\rm{CP}}$ in the neutrino sector and $G^{l}_{\rm{CP}}\cong Z^{T}_3\rtimes H^{l}_{\rm{CP}}$ in the charged lepton sector, leading to the prediction of no CP violation, namely $\delta_{CP}$ and the Majorana phases $\alpha_{21}$ and $\alpha_{31}$ are all equal to either zero or $\pi$. We then propose an effective supersymmetric model based on the symmetry $A_4\rtimes H_{\rm{CP}}$ in which trimaximal lepton mixing is predicted together with either zero CP violation or $\delta_{CP}\simeq\pm \pi/2$ with non-trivial Majorana phases. An ultraviolet completion of the effective model yields a neutrino mass matrix which depends on only three real parameters. As a result of this, all three CP phases and the absolute neutrino mass scale are determined, the atmospheric mixing angle is maximal, and the Dirac CP can either be preserved with $\delta_{CP}=0,\pi$ or maximally broken with $\delta_{CP}=\pm \pi /2$ and sharp predictions for the Majorana phases and neutrinoless double beta decay.