Shell model description of the $N=82$ isotonic chain with a new effective interaction

TL;DR

This paper develops a new effective interaction for shell model calculations of the N=82 isotonic chain, accurately reproducing experimental data and predicting properties of nuclei beyond current experimental reach.

Contribution

Introduces a high-quality, systematically optimized effective interaction for shell model studies of N=82 isotones, improving predictive accuracy.

Findings

Accurately reproduces experimental energy levels with a 102 keV RMS deviation.

Successfully predicts electromagnetic properties across isotones.

Provides reliable predictions for nuclei beyond current experimental data.

Abstract

In this work, we present a systematic study of low-lying states and electromagnetic properties of the semi-magic $N = 82$ isotonic chain with proton number $Z=51$-77, using the full configuration interaction shell model with a newly developed high-quality effective interaction. The calculations are performed in a large model space that includes all proton orbitals between $Z = 50$ and 82: $0g_{7/2}$, $1d_{5/2}$, $1d_{3/2}$, $2s_{1/2}$, and $0h_{11/2}$. The effective interaction is derived through the principal component analysis approach, starting from 160 two-body matrix elements and 5 single-particle energies and considering up to 30 degrees of freedom. Those are optimized by fitting to 204 available experimental energy levels. The resulting root-mean-square deviation is as low as 102 keV. The new interaction successfully reproduces the binding energies, low-lying spectra, electric quadrupole transition probabilities $B(E2)$, and magnetic dipole moments across both even-even and odd-mass isotones. The nuclear structure of low-lying states is analyzed in detail. Additionally, predictions are made for several more proton-rich nuclei beyond current experimental reach, including $^{155}\mathrm{Ta}$, $^{156}\mathrm{W}$, $^{157}\mathrm{Re}$, $^{158}\mathrm{Os}$, and $^{159}\mathrm{Ir}$.