Phenomenology of keV sterile neutrino in minimal extended seesaw

Abstract

We explore the possibility of a single generation of keV scale sterile neutrino (mS) as a dark matter candidate within the minimal extended seesaw (MES) framework and it's influence in neutrinoless double beta decay (0ββ) study. Three hierarchical right-handed neutrinos were considered to explain neutrino mass. We also address baryogenesis via the mechanism of thermal leptogenesis considering the decay of the lightest RH neutrino to a lepton and Higgs doublet. A generic model based on A4× Z4× Z3 flavor symmetry is constructed to explain both normal and inverted hierarchy mass pattern of neutrinos. Significant results on effective neutrino masses are observed in presence of sterile mass (mS) and active-sterile mixing (θS) in 0ββ. Results from 0ββ give stringent upper bounds on the active-sterile mixing matrix element. To establish sterile neutrino as dark matter within this model, we checked decay width and relic abundance of the sterile neutrino, which restricted sterile mass (mS) within some definite bounds. Constrained regions on the CP-phases and Yukawa couplings are obtained from 0ββ and baryogenesis results. Co-relations among these observable are also established and discussed within this framework.