Isomer triplets in odd-odd transitional rare earth nuclei: unique features, orbital systematics and characterization

TL;DR

This paper investigates unique isomer triplets in odd-odd light rare-earth nuclei, revealing their systematics, orbital configurations, and the role of high-spin intruder neutron orbitals using experimental data and the Two Quasiparticle Rotor Model.

Contribution

It identifies and analyzes isomer triplets in specific odd-odd nuclei, providing detailed orbital systematics and elucidating their formation mechanisms, which is a novel insight in nuclear structure physics.

Findings

Identification of isomer triplets in nine odd-odd nuclei.

Systematic analysis of single-quasiparticle orbitals near the Fermi surface.

Highlighting the role of high-spin intruder neutron orbitals in isomer formation.

Abstract

The existence of low-lying long-lived isomers, predominantly in odd-odd nuclei of the light rare-earth mass region, is investigated through an extensive survey of available nuclear data. The characteristics of these isomeric states and their systematics has revealed intriguing and unusual properties, including the identification of isomer triplets, a phenomenon specific to odd-odd deformed nuclei close to the transition region. This exclusive feature was observed in the following odd-odd nuclei, namely, 152Pm, 152Eu, 154Tb, 156Tb, 156Ho, 158Ho, 160Ho, 162Lu and 166Lu. We present a detailed overview of these isomer triplets by exploring the systematics of single-quasiparticle proton and neutron orbitals near the Fermi surface relevant in this mass region, to elucidate the factors responsible for their formation. The low-lying level structures of 156Tb and 154Tb, were constructed using the well-tested Two Quasiparticle Rotor Model to resolve the ambiguities in the spin, parity, energy and orbital configuration of these isomeric states. These results were extended to study the systematics of low-lying isomer triplets in the other five light rare-earth nuclei of interest. Our review and analysis of 1qp proton and neutron orbital systematics in the neighboring odd-mass isotopes and isotones highlights the crucial role of high-spin intruder neutron orbital in the formation of these isomer triplets.