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Shape variables and the shell model

  • Nuclear Structure and Spectroscopy
  • Published:
Zeitschrift für Physik A Atomic Nuclei

Abstract

The irreducible representation labelsλ andμ of the SU(3) shell model are related to the shape variablesβ andγ of the collective model by invoking a linear mapping between eigenvalues of invariant operators of the two theories. All but one parameter of the theory is fixed if the shell-model result is required to reproduce the collective-model geometry. And for one special value of the remaining free parameter there is a simple linear relationship between the eigenvalues, λα, of the quadrupole matrix of the collective model and the SU(3) representation labels:

$$\lambda _1 = ( - \lambda + \mu )/3, \lambda _2 = ( - \lambda + 2\mu + 3)/3, \lambda _3 = (2\lambda + \mu + 3)/3.$$

The correspondence between hamiltonians that describe rotations in each theory is also given. Results are shown for two cases,24Mg and168Er, to demonstrate that the simplest mapping yields excellent results for both energies and transition rates. For λ and/or μ large, the (β, γ)↔(λ,μ) correspondence introduced here reduces to the symplectic shell-model result.

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Author notes

  1. O. Casta∼nos

    Present address: Centro de Estudios Nucleares, UNAM, Apdo. Postal 70-543, México, D.F., México

Authors and Affiliations

  1. Department of Physics and Astronomy, Louisiana State University, Baton Rouge, Louisiana, USA

    O. Casta∼nos, J. P. Draayer & Y. Leschber

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  1. O. Casta∼nos
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  2. J. P. Draayer
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  3. Y. Leschber
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Supported in part by a grant from the U.S. National Science Foundation

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Casta∼nos, O., Draayer, J.P. & Leschber, Y. Shape variables and the shell model. Z. Physik A - Atomic Nuclei 329, 33–43 (1988). https://doi.org/10.1007/BF01294813

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  • DOI: https://doi.org/10.1007/BF01294813

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