Energy density functional analysis of shape evolution in N=28 isotones

Li, Z. P. and Yao, J. M. and Vretenar, Dario and Nikšić, Tamara and Chen, H. and Meng, Jie (2011) Energy density functional analysis of shape evolution in N=28 isotones. Physical Review C, 84 (5). pp. 54304-12. ISSN 0556-2813

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Abstract

The structure of low-energy collective states in proton-deficient N = 28 isotones is analyzed using structure models based on the relativistic energy density functional DD-PC1. The relativistic Hartree-Bogoliubov model for triaxial nuclei is used to calculate binding energy maps in the β-γ plane. The evolution of neutron and proton single-particle levels with quadrupole deformation, and the occurrence of gaps around the Fermi surface, provide a simple microscopic interpretation of the onset of deformation and shape coexistence. Starting from self-consistent constrained energy surfaces calculated with the functional DD-PC1, a collective Hamiltonian for quadrupole vibrations and rotations is employed in the analysis of excitation spectra and transition rates of 46Ar, 44S, and 42Si. The results are compared to available data, and previous studies based either on the mean-field approach or large-scale shell-model calculations. The present study is particularly focused on 44S, for which data have recently been reported that indicate pronounced shape coexistence.

Item Type: Article
Date: November 2011
Subjects: NATURAL SCIENCES > Physics > Nuclear Physics
Additional Information: Copyright (2011) by the American Physical Society.
Divisions: Faculty of Science > Department of Physics
Project code: 119-1191005-1010
Publisher: American Physical Society
Depositing User: Gordana Stubičan Ladešić
Date Deposited: 01 Jun 2014 07:57
Last Modified: 24 Feb 2016 15:00
URI: http://digre.pmf.unizg.hr/id/eprint/2058

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