Systematic study of the half-lives of nuclear bound-state β- decay

Abstract

Nuclear bound-state β- decay (β b decay) is a novel weak-interaction process that becomes possible when atoms are highly ionized, such as in stellar environments or heavy-ion storage rings. In this work we present a systematic theoretical calculations for the β b-decay half-lives of interesting candidates for the first time, where both allowed Gamow-Teller transitions and first-forbidden transitions are taken into account by the microscopic projected shell model, and the lepton phase space is calculated by the Takahashi-Yokoi model. We analyzed the structure informations for hundreds of nuclei near the β-stability line, and select 16 interesting candidates belonging to two categories, i.e., nuclei with negative Q values and positive Q values in neutral atoms respectively. Among these candidates, we recommend 243Am95+, 194Os76+, 227Ac89+, 228Ra88+, 241Pu94+, 247Cm96+ and 250Cm96+ as promising ones for future studies of storage-ring experiments because their βb-decay half-lives are predicted to be much shorter than the half-lives in neutral atoms. These findings provide essential nuclear inputs for astrophysical models and identify specific candidates where experimental verification would be most valuable.