Fingerprints of the triaxial deformation from energies and $B(E2)$ transition probabilities of $\gamma$-bands in transitional and deformed nuclei

TL;DR

This paper investigates the fingerprints of triaxial deformation in nuclei by analyzing energies and $B(E2)$ transition probabilities of $g$-bands using the triaxial projected shell model, revealing characteristic staggering patterns.

Contribution

It introduces a detailed analysis of $g$-band staggering phenomena and proposes an analog staggering of intra-$g$ $B(E2)$ transitions, linking them to triaxial shape effects.

Findings

Good agreement of TPSM predictions with experimental data.

Identification of characteristic energy staggering patterns.

First introduction of analog staggering in $B(E2)$ transitions.

Abstract

The energies and $B(E2)$ transitions involving the states of the ground- and $\gamma$-bands in thirty transitional and deformed nuclei are calculated using the triaxial projected shell model (TPSM) approach. Systematic good agreement with the existing data substantiates the reliability of the model predictions. The Gamma-rotor version of the collective Bohr Hamiltonian is discussed in order to quantify the classification with respect to the triaxial shape degree of freedom. The pertaining criteria are applied to the TPSM results and the staggering of the energies of the $\gamma$-bands is analyzed in detail. An analog staggering of the intra-$\gamma$ $B(E2,I\rightarrow I-2)$ is introduced for the first time. The emergence of the staggering phenomena in the transitions is explained in the terms of interactions between the bands.