Neutrino Masses with Enhanced B-L Symmetry

Abstract

Assuming all three known neutrinos are Dirac fermions, U(1)B-L can be an exact symmetry. We show that, if the condition of charge quantization is relaxed, the anomaly-free B-L charges of two out of three right-handed neutrinos can be enhanced by arbitrarily large factors, while all other fermions retain their canonical charges. We call this setup as `enhanced B-L symmetry' and promote it to be local. As long as this enhanced B-L gauge symmetry remains unbroken, neutrinos stay chiral and massless at low energies. Nonzero neutrino masses then require sub-eV-scale symmetry breaking order parameters, which we associate with gravity-induced neutrino condensate. If the enhancement is large and the B-L gauge boson A' is lighter than the heaviest neutrino, then the neutrino decay into A' directly constrains the gauge coupling, which can be significantly stronger than the baryon-based fifth-force tests. Through kinetic mixing with the photon, A' can also mediate neutrino-electron and coherent neutrino-nucleus scatterings, leading to possible signatures in neutrino observatories and dark matter detectors.