English

Partial dynamical symmetries and shape coexistence in nuclei

Nuclear Theory 2017-11-17 v1 Nuclear Experiment Quantum Physics

Abstract

We present a symmetry-based approach for shape coexistence in nuclei, founded on the concept of partial dynamical symmetry (PDS). The latter corresponds to a situation when only selected states (or bands of states) of the coexisting configurations preserve the symmetry while other states are mixed. We construct explicitly critical-point Hamiltonians with two or three PDSs of the type U(5), SU(3), SU(3){\overline{\rm SU(3)}} and SO(6), appropriate to double or triple coexistence of spherical, prolate, oblate and γ\gamma-soft deformed shapes, respectively. In each case, we analyze the topology of the energy surface with multiple minima and corresponding normal modes. Characteristic features and symmetry attributes of the quantum spectra and wave functions are discussed. Analytic expressions for quadrupole moments and E2E2 rates involving the remaining solvable states are derived and isomeric states are identified by means of selection rules.

Keywords

Cite

@article{arxiv.1708.06321,
  title  = {Partial dynamical symmetries and shape coexistence in nuclei},
  author = {A. Leviatan and N. Gavrielov},
  journal= {arXiv preprint arXiv:1708.06321},
  year   = {2017}
}

Comments

25 pages, 14 figures, accepted for publication as a Special Issue on "Shapes and Symmetries in Nuclei: From Experiment to Theory" in Physica Scripta

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