Magic neutrino mass model with broken μ − τ symmetry and leptogenesis

Abstract

We investigate baryogenesis via leptogenesis in an A4 flavor model within the paradigm of type-I and II seesaw mechanism resulting in a magic neutrino mass matrix with broken μ − τ symmetry in a minimal scenario with two right-handed neutrinos (2RHN). Additional Z3 cyclic symmetry is employed to constrain the Yukawa structure of the model. The type-II seesaw terms play a crucial role in generating non-degenerate neutrino masses and non-zero θ13 and contribute to baryogenesis. In particular, after the spontaneous symmetry breaking, the Yukawa couplings and are responsible for the breaking of μ − τ symmetry. The effective Majorana neutrino mass is found to be well within the sensitivity reach of the 0νββ experiments, in particular, for inverted hierarchy. The model has an imperative implication for inverted hierarchy, for example, the non-observation of this process at nEXO will rule out IH. The predicted baryon asymmetry is in good agreement with the observed baryon asymmetry for NH whereas IH is disallowed at 2.5σ C.L.