Quantifying neutron-proton interactions in $N=51$ isotones: from NEEC candidate $^{93}$Mo to $^{99}$Cd

TL;DR

This study uses shell-model analysis to understand neutron-proton interactions in $N=51$ isotones, revealing their influence on isomeric states and implications for nuclear excitation by electron capture, with a focus on $^{93}$Mo.

Contribution

It provides a detailed comparison of proton-proton and neutron-proton matrix elements in $N=51$ isotones, highlighting the unique neutron-proton interaction in $^{93}$Mo that affects its isomeric behavior.

Findings

Neutron-proton interaction dominates in $^{93}$Mo.

$E2$ transition strength is reduced by 40%.

Structural evolution suppresses isomerism in neighboring isotones.

Abstract

We present a shell-model analysis of $N=51$ isotones, $^{93}$Mo, $^{95}$Ru, $^{97}$Pd, and $^{99}$Cd, to quantify the role of neutron-proton interactions in shaping the location and half-life of isomeric states. The study is motivated by the anomalous behavior of the ${21/2}^+$ isomeric state in $^{93}$Mo, a prominent candidate for nuclear excitation by electron capture (NEEC), which misses an $E2$ decay branch due to a higher-lying ${17/2}^+$ state and instead proceeds via a long-lived $E4$ isomeric transition. Employing a consistent configuration space and empirically derived effective interaction, we extract and compare the proton-proton and neutron-proton matrix elements for the four $N=51$ isotones. Our results show a distinct dominance of the neutron-proton interaction in $^{93}$Mo, in contrast to its neighbors--$^{95}$Ru, $^{97}$Pd, and $^{99}$Cd--where no analogous isomeric behavior emerges due to structural evolution. These findings reveal that the favorable structure for NEEC in $^{93}$Mo stems from subtle interaction systematics that do not persist across the chain. We find that the $E2$ strength of the key NEEC transition is reduced by 40\% compared to the previously estimated value. The analysis provides microscopic insights into the origin of long-lived isomerism in medium-mass nuclei and outlines a framework for identifying future candidates in other mass regions for exploiting the potential energy storage capacities of isomeric states.