Triaxial nuclear shapes from simple ratios of electric-quadrupole matrix elements

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Date

2025

Journal Title

Journal ISSN

Volume Title

Publisher

Elsevier Inc.

Abstract

Theoretical models often invoke axially-asymmetric nuclear shapes to explain elusive collective phenomena, but such an assumption is not always easy to confirm experimentally. The only model-independent measurement of the nuclear axial asymmetry (or triaxiality) γ is based on rotational invariants of zero-coupled products of the electric-quadrupole (E2) operator — the Kumar-Cline sum rule analysis — which generally requires knowledge of a large number of E2 matrix elements connecting the state of interest. We propose an alternative method to determine γ using only two E2 matrix elements, which are among the easiest to measure. This approach is based on a standard rotational description of a nucleus with stable triaxial deformation, where all underlying assumptions are either empirically proven or unnecessary. It is applied to the 2+ states of the ground-state and the γ bands of even–even nuclei and is model-independent provided these 2+ states have rotational nature. This technique was applied to a number of deformed even–even nuclei for which the ratio of the energies of the yrast 4+ and 2+ states was R4/2> 2.4. Where sufficient experimental data were available for performing Kumar-Cline analysis, good agreement was observed between the γ values deduced in these two approaches. The agreement shows that (i) the 2+ states of the selected nuclei have indeed rotational nature, and (ii) the proposed method represents a simple and reliable deduction of γ. In the present work more than 60 even–even rotating nuclei were associated with axially-asymmetric nuclear shapes.

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Keywords

Electric-quadrupole matrix elements, Irrotational flow model, Model-independent evaluation of γ, Multi-step Coulomb excitation, Quadrupole deformation

Citation

Lawrie, E.A. and Orce, J.N., 2024. Triaxial nuclear shapes from simple ratios of electric-quadrupole matrix elements. arXiv preprint arXiv:2411.08130.