Complex $S_3$-symmetric 3HDM

TL;DR

This paper investigates a three-Higgs-doublet model with $S_3$ symmetry, exploring conditions for explicit and spontaneous CP violation, and analyzing the implications for scalar and Yukawa sectors, including potential light scalars.

Contribution

It provides a comprehensive classification of vacuum structures and CP violation sources in an $S_3$ symmetric 3HDM without soft breaking, including numerical analysis of the scalar spectrum.

Findings

Possible CP violation arises from different vacuum configurations.

Light neutral scalars at the MeV scale can emerge under constraints.

The model's parameter space accommodates both explicit and spontaneous CP violation.

Abstract

CP violation plays a very important role in nature with implications both for Particle Physics and for Cosmology. Accounting for the observed matter anti-matter asymmetry of the Universe requires the existence of new sources of CP violation beyond the Standard Model. In models with an extended scalar sector CP violation can emerge either explicitly, i.e., at the Lagrangian level, or spontaneously. In the context of multi-Higgs extensions of the Standard Model imposing the existence of a scalar basis where all couplings are real is a sufficient condition for CP to be explicitly conserved. We discuss a three-Higgs-doublet model with an underlying $S_3$ symmetry, allowing in principle for complex couplings. In this framework it is possible to have either spontaneous or explicit CP violation in the scalar sector, depending on the regions of parameter space corresponding to the different possible vacua of the $S_3$ symmetric potential. We list all possible vacuum structures allowing for CP violation in the scalar sector specifying whether it can be explicit or spontaneous. It is by now established that CP is violated in the flavour sector and that the Cabibbo-Kobayashi-Maskawa matrix is complex. In order to understand what are the possible sources of CP violation in the Yukawa sector we analyse the implications of the different available choices of representations for the quarks under the $S_3$ group. This classification is based strictly on the exact $S_3$-symmetric scalar potential with no soft symmetry breaking terms. The scalar sector of one such model was explored numerically. After applying the theoretical and the most important experimental constraints the available parameter space is shown to be able to give rise to light neutral scalars at the $\mathcal{O}(\text{MeV})$ scale.