How to interpret a discovery or null result of the 0 2β decay

Abstract

The Majorana nature of massive neutrinos will be crucially probed in the next-generation experiments of the neutrinoless double-beta (0 2β) decay. The effective mass term of this process, mee, may be contaminated by new physics. So how to interpret a discovery or null result of the 0 2β decay in the foreseeable future is highly nontrivial. In this paper we introduce a novel three-dimensional description of | mee|, which allows us to see its sensitivity to the lightest neutrino mass and two Majorana phases in a transparent way. We take a look at to what extent the free parameters of | mee| can be well constrained provided a signal of the 0 2β decay is observed someday. To fully explore lepton number violation, all the six effective Majorana mass terms mαβ (for α, β = e, μ, τ) are calculated and their lower bounds are illustrated with the two-dimensional contour figures. The effect of possible new physics on the 0 2β decay is also discussed in a model-independent way. We find that the result of | mee| in the normal (or inverted) neutrino mass ordering case modified by the new physics effect may somewhat mimic that in the inverted (or normal) mass ordering case in the standard three-flavor scheme. Hence a proper interpretation of a discovery or null result of the 0 2β decay may demand extra information from some other measurements.