Tentative sensitivity of future 0 ββ-decay experiments to neutrino masses and Majorana CP phases

Abstract

In the near future, the neutrinoless double-beta (0ββ) decay experiments will hopefully reach the sensitivity of a few meV to the effective neutrino mass |mββ|. In this paper, we tentatively examine the sensitivity of future 0ββ-decay experiments to neutrino masses and Majorana CP phases by following the Bayesian statistical approach. Provided experimental setups corresponding to the sensitivity of |mββ| 1~ meV, the null observation of 0ββ decays in the case of normal neutrino mass ordering leads to a very competitive bound on the lightest neutrino mass m1. Namely, the 95\% credible interval turns out to be 1.6~ meV m1 7.3~ meV or 0.3~ meV m1 5.6~ meV when the uniform prior on m1/ eV or on 10(m1/ eV) is adopted. Moreover, one of two Majorana CP phases is strictly constrained, i.e., 140 220 for both priors of m1. In contrast, if a relatively worse sensitivity of |mββ| 10~ meV is assumed, the constraint becomes accordingly 0.6~ meV m1 26~ meV or 0 m1 6.1~ meV, while two Majorana CP phases will be essentially unconstrained. In the same statistical framework, the prospects for the determination of neutrino mass ordering and the discrimination between Majorana and Dirac nature of massive neutrinos in the 0ββ-decay experiments are also discussed. Given the experimental sensitivity of |mββ| 10~ meV (or 1~ meV), the strength of evidence to exclude the Majorana nature under the null observation of 0ββ decays is found to be inconclusive (or strong), no matter which of two priors on m1 is taken.