Skyrme SV density-functional analysis of the 2νββ decay in 76Ge

Abstract

We present a theoretical study of the two-neutrino 0+ → 0+ double beta decay of 76Ge within the No-Core Configuration-Interaction framework based on the Skyrme SV density functional. We analyze three allowed decay scenarios distinguished by the [n,m] [(νg9/2)n, (πg9/2)m] occupancy of the 0g9/2 intruder orbital, which remains conserved to high precision, as well as by the triaxiality of the daughter nucleus. The resulting 2νββ nuclear matrix element is found to depend strongly on the scenario. For the energetically favored [4,2] occupancy, we obtain |M2ν| = 0.069(7)~MeV-1. For the [6,0] occupancy, the matrix element further depends on the triaxiality parameter γ of the two coexisting, closely lying minima in 76Se, yielding |M2ν| = 0.040(4)~MeV-1 at γ= 17.7 and |M2ν| = 0.22(2)~MeV-1 at γ= 41.9. The latter result is consistent with the empirical value reported by A. S. Barabash, |M2ν| = 0.204(14)~MeV-1, while the two former results are comparable to existing calculations based on energy-density-functional frameworks. Our calculations reveal challenges in the precise determination of the |M2ν| for the 76Ge decay. The structural complexity, triaxiality, and shape coexistence identified in the analyzed nuclei imply a strong sensitivity to fine details of the interaction and configuration mixing. This, in turn, explains the difficulties in theoretical modeling of the |M2ν| matrix elements for the 76Ge decay, which vary by almost an order of magnitude in the available literature.