The Simplest Dirac Scoto-Seesaw Realization

Abstract

We present a simple Dirac scoto-seesaw framework based on the anomaly-free U(1)B-L charge assignment (-4,-4,5) for νR. This chiral charge assignment naturally accounts for the observed neutrino mass-squared differences, with Δm2 atm generated at tree level and Δm2 sol arising radiatively. After the spontaneous breaking of gauged U(1)B-L, a residual Z6 symmetry stabilizes the dark matter candidate. We investigate two minimal realizations of the framework, finding that both normal and inverted orderings are viable in one case, whereas only normal ordering survives in the other, with distinctive features for neutrino observables. Moreover, the chiral nature of the U(1)B-L charges suppresses the dilepton branching fraction of Z', resulting in weaker ATLAS mass bounds than in the conventional vector B-L scenario, thereby easing constraints on the dark sector. We explore the dark matter phenomenology of the singlet scalar and fermionic dark matter candidates. While singlet scalar DM is often severely constrained, the presence of the Z' portal together with annihilation and co-annihilation channels substantially broadens the allowed parameter space. Thus, the framework offers a predictive scenario for neutrino and dark matter phenomenology that can be probed in future experiments.