Minimally Allowed Neutrinoless Double Beta Decay Rates From Approximate Flavor Symmetries

Abstract

Neutrinoless double beta decay (ββ0) is among the only realistic probes of Majorana neutrinos. In the standard scenario, dominated by light neutrino exchange, the process amplitude is proportional to mee, the e-e element of the Majorana mass matrix. Naively, current data allows for vanishing mee, but this should be protected by an appropriate flavor symmetry. All such symmetries lead to mass matrices inconsistent with oscillation phenomenology. I perform a spurion analysis to break all possible Abelian symmetries that guarantee vanishing ββ0 rates and search for minimally allowed values. I survey 230 broken structures to yield mee values and current phenomenological constraints under a variety of scenarios. This analysis also extracts predictions for both neutrino oscillation parameters and kinematic quantities. Assuming reasonable tuning levels, I find that mee>4× 10-6 eV at 99% confidence. Bounds below this value might indicate the Dirac neutrino nature or the existence of new light (eV-MeV scale) degrees of freedom that can potentially be probed elsewhere.