Beta-decay rates of extreme neutron-rich nuclei remain largely unknown experimentally, while they are critical inputs for r-process nucleosynthesis. We present first ab initio calculations of total beta-decay half-lives, with a focus on N=50 nuclei. Starting from nuclear forces and currents based on chiral effective field theory, we use the in-medium similarity renormalization group to consistently derive valence-space Hamiltonians and weak operators, from which we calculate the nuclear states involved and the Gamow-Teller transition strengths, without phenomenological adjustments. In addition, we explore effects of first-forbidden contributions. Our results show that the inclusion of two-body currents increases the total half-lives, which then show good agreement with the existing experimental data, thereby validating the predictive capability of our approach.
Li et al. (Mon,) studied this question.
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