Large-scale shell-model study of 2 process in 78Kr
Abstract
In this work, we present the systematic study of 2 process in the 78Kr using large-scale shell-model calculations with the GWBXG effective interaction. We first validate the efficiency of the utilized interaction by comparing the theoretical low-lying energy spectra, the kinematic moment of inertia, and reduced transition probabilities with the experimental data for both the parent and grand-daughter nuclei 78Kr and 78Se, respectively. Additionally, we examine the shell-model level densities of the 1+ states in the intermediate nucleus 78Br, comparing them with the predictions from the Back-shifted Fermi gas model. We analyze the variation of cumulative nuclear matrix elements (NMEs) for the 2 process in 78Kr as a function of 1+ state energies in the intermediate nucleus 78Br up to the saturation level. Our estimated half-life for 78Kr, extracted from the shell-model predicted NMEs, shows good agreement with the experimental value. The Gamow-Teller transitions from the lowest 1+ state of 78Br via both the EC+β+ and β--channels are also discussed.
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