Two-neutrino double-beta decay matrix elements based on relativistic nuclear energy density functional

Abstract

Nuclear matrix elements (NMEs) for two-neutrino double-beta decay (2ββ) are studied in the framework of relativistic nuclear energy density functional (REDF). The properties of nuclei involved in the decay are obtained using the relativistic Hartree-Bardeen-Cooper-Schrieffer theory and relevant nuclear transitions are described using the relativistic proton-neutron quasiparticle random phase approximation based on relativistic energy density functional (REDF-QRPA). Three effective interactions have been employed, including density-dependent meson-exchange (DD-ME2) and point coupling interactions (DD-PC1 and DD-PCX), and pairing correlations are described consistently both in T=1 and T=0 channels using a separable pairing interaction. The optimal values of T=0 pairing strength parameter V0pp are constrained by the experimental data on β-decay half lives. The 2ββ matrix elements and half-lives are calculated for several nuclides experimentally known to undergo this kind of decay: 48Ca, 76Ge, 82Se, 96Zr, 100Mo, 116Cd, 124Xe, 128Te, 130Te, 136Xe and 150Nd. The model dependence of the NMEs and their sensitivity on V0pp is investigated, and the NMEs obtained using optimal values of V0pp are discussed in comparison to previous studies. The results of the present work represent an important benchmark for the future applications of the relativistic framework in studies of neutrinoless double-beta decay.