Half-life of 136Xe for neutrinoless double-β decay calculated with effective axial-vector current coupling unified for two-neurtino and neutrinoless double-β decay modes

Abstract

The upper limit on the mass of the Majorana neutrino, extracted from the limits on the nonobservation of the neutrinoless double-β (0ββ) decay, is hampered by uncertainties in the matrix elements of the transition operators. Recently, we have shown that the values of the effective axial-vector current coupling constants (gAeff) for the 0ββ and the two-neutrino double-β decays are close. This striking result was obtained for the first time by including vertex corrections and two-body currents in these matrix elements. In this letter, we calculate the half-life for the 0ββ decay (T1/20) of 136Xe using this closeness and show the convergence of the half-life with respect to the variation of the method to determine gAeff. The closeness of the gAeff of the two decay modes plays a decisive role in predicting T1/20. The appropriate value of gAeff depends on the assumptions made for the sectors of the nuclear structure and transition operators of the calculations within the perturbation scheme. The value gAeff≈ 1 is obtained when the SkM is used to describe the nuclear structure component, while a smaller value of gAeff is obtained by applying a less realistic interaction like the SGII one.