Fermion Masses and Mixings and Dark Matter Constraints in a Model with Radiative Seesaw Mechanism

TL;DR

This paper presents a predictive fermion mass and mixing model based on a $(27)$ symmetry, incorporating a radiative seesaw mechanism, and explores its implications for neutrino physics and dark matter candidates.

Contribution

It introduces a novel $(27)$ symmetry-based model that links fermion masses, mixings, and dark matter, with specific predictions for neutrino hierarchy and dark matter properties.

Findings

Model favors inverted neutrino mass hierarchy.

Predicts a specific correlation between $ heta_{23}$ and $ heta_{13}$.

Identifies viable dark matter candidates, including scalar WIMP and fermionic FIMP.

Abstract

We formulate a predictive model of fermion masses and mixings based on a $\Delta(27)$ family symmetry. In the quark sector the model leads to the viable mixing inspired texture where the Cabibbo angle comes from the down quark sector and the other angles come from both up and down quark sectors. In the lepton sector the model generates a predictive structure for charged leptons and, after radiative seesaw, an effective neutrino mass matrix with only one real and one complex parameter. We carry out a detailed analysis of the predictions in the lepton sector, where the model is only viable for inverted neutrino mass hierarchy, predicting a strict correlation between $\theta_{23}$ and $\theta_{13}$. We show a benchmark point that leads to the best-fit values of $\theta_{12}$, $\theta_{13}$, predicting a specific $\sin^2\theta_{23} \simeq 0.51$ (within the $3 \sigma$ range), a leptonic CP-violating Dirac phase $\delta \simeq 281.6 ^\circ$ and for neutrinoless double-beta decay $m_{ee} \simeq 41.3$ meV. We turn then to an analysis of the dark matter candidates in the model, which are stabilized by an unbroken $\mathbb{Z}_2$ symmetry. We discuss the possibility of scalar dark matter, which can generate the observed abundance through the Higgs portal by the standard WIMP mechanism. An interesting possibility arises if the lightest heavy Majorana neutrino is the lightest $\mathbb{Z}_2$-odd particle. The model can produce a viable fermionic dark matter candidate, but only as a feebly interacting massive particle (FIMP), with the smallness of the coupling to the visible sector protected by a symmetry and directly related to the smallness of the light neutrino masses.