Flavor origin of dark matter and its relation with leptonic nonzero $\theta_{13}$ and Dirac CP phase $\delta$

TL;DR

This paper links dark matter relic abundance with leptonic mixing angles and CP phase through a flavor symmetry extension of the standard model, predicting testable dark matter charge properties.

Contribution

It introduces a minimal U(1) flavor symmetry extension that correlates dark matter stability, neutrino mixing deviations, and leptonic CP violation, providing new testable predictions.

Findings

Dark matter charge under U(1) predicts non-zero 3

Deviation from tri-bimaximal mixing explains 3

Non-zero leptonic CP phase  influences dark matter properties

Abstract

We propose a minimal extension of the standard model by including a $U(1)$ flavor symmetry to establish a correlation between the relic abundance of dark matter, measured by WMAP and PLANCK satellite experiments and non-zero value of $\sin \theta_{13}$ observed at DOUBLE CHOOZ, Daya Bay, RENO and T2K. The flavour symmetry is allowed to be broken at a high scale to a remnant $\mathcal{Z}_2$ symmetry, which not only ensures the stability to the dark matter, but also gives rise to a modification to the existing $A_4$-based tri-bimaximal neutrino mixing. This deviation in turn suggests the required non-zero value of $\sin \theta_{13}$. We assume the dark matter to be neutral under the existing $A_4$ symmetry while charged under the $U(1)$ flavor symmetry. Hence in this set-up, the non-zero value of $\sin \theta_{13}$ predicts the dark matter charge under $U(1)$, which can be tested at various ongoing and future direct and collider dark matter search experiments. We also point out the involvement of nonzero leptonic CP phase $\delta$, which plays an important role in the analysis.