Vibrational Modes in Strongly Deformed Nuclei

TL;DR

This paper uses advanced shell model calculations to identify and analyze vibrational excitations in strongly deformed nuclei, revealing complex structures and predicting new states for future experimental verification.

Contribution

It introduces an extended T-plot method within the Monte Carlo Shell Model to distinguish vibrational states from rotational excitations in heavy deformed nuclei.

Findings

Vibrational states are identified above the gamma band in $^{166}$Er and $^{162}$Dy.

Shape coexistence produces low-lying states below vibrational band heads.

Some predicted states have experimental counterparts, others are novel predictions.

Abstract

Low-energy vibrational excitations associated with the fluctuation of quadrupole deformed shapes are discussed within the frame of state-of-the-art Configuration Interaction calculations, actually performed via the Quasi-particle Vacua Shell Model version of the Monte Carlo Shell Model. Recently, low-lying $\gamma$ bands in heavy strongly deformed nuclei were shown to be rotational $K^P$ = 2$^+$ excitations of triaxially deformed states (see T. Otsuka \etal, Eur. Phys. J. A 61, 126 (2025)) rather than vibrational excitations as traditionally interpreted. In this context, it is important to identify possible low-lying vibrational excitations and to characterize the excitation energy at which they emerge. Focusing on two typical examples, $^{166}$Er and $^{162}$Dy, vibrational states are indeed identified above the $\gamma$ band using an extended version of the so-called T-plot. The phenomenon of shape coexistence is also shown to produce low-lying states below such vibrational band heads. These results suggest novel and rich structures in heavy deformed nuclei. While experimental counterparts are seen for some of such states, others are predictions opening doors to future dedicated experiments.