Naturally small Dirac neutrino mass and B-L dark matter

Abstract

In the conventional gauged B-L extension of the standard model, the B-L charge of the singlet scalar , responsible for the breaking of U(1)B-L symmetry, is taken to be 2 such that it can anchor type-I seesaw by giving Majorana masses to the right-handed neutrinos, R. In this paper, we consider instead the cases 3 or 4 under B-L, so that R may not acquire any Majorana mass and neutrinos are Dirac fermions. We then consider a vector-like fermion S with 2 units of B-L charge, which becomes a good candidate for dark matter, either Dirac for 3 or Majorana for 4. In both cases, spontaneous B-L breaking can induce a strong first-order phase transition, producing stochastic gravitational waves (GW) which can be tested at GW experiments. Moreover, the presence of light Rs gives rise to an additional contribution to the effective number of relativistic degrees of freedom, N eff, providing complementary constraints from current and upcoming CMB observations.