Nuclear β-decay half-lives within the subtracted second random-phase approximation

Abstract

We employ, within the framework of Skyrme energy-density functional theory, the subtracted second random-phase approximation, recently developed for charge-exchange excitations, to compute β-decay half-lives in four nuclei, 24O, 34Si, 78Ni, and 132Sn. Following our recent results on the description of the Gamow-Teller strength, we proceed coherently in the present work by computing β-decay half-lives using the bare value of the axial-vector coupling constant gA. Half-lives are thus obtained, within the allowed Gamow-Teller approximation, without the use of any ad hoc quenching factors. A genuine quenching is indeed microscopically introduced in our model owing to the correlations induced by the coupling of one-particle one-hole configurations with two-particle two-hole ones. The role of the so-called J2 terms is also studied. By comparing our results with experimental data, we show a general improvement of β-decay half-lives with respect to results obtained within the commonly used Random Phase Approximation (RPA). The inclusion of the two-particle two-hole configurations produces a more fragmented and richer spectrum within the β-window, resulting in lower β half-lives with respect to the RPA ones.