SU(3) quasidynamical symmetry as an organizational mechanism for generating nuclear rotational motions - INSPIRE

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SU(3) quasidynamical symmetry as an organizational mechanism for generating nuclear rotational motions

C. Bahri
(
- Toronto U.
)
,
D.J. Rowe
(
- Toronto U.
)

Jun, 1999

19 pages

Published in:

Nucl.Phys.A 662 (2000) 125-147

e-Print:

nucl-th/9906039 [nucl-th]

DOI:

10.1016/S0375-9474(99)00394-2

Report number:

UTNT-9901

View in:

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Abstract:

The phenomenological symplectic model with a Davidson potential is used to construct rotational states for a rare-earth nucleus with microscopic wave functions. The energy levels and E2 transitions obatined are in remarkably close agreement (to within a few percent) with those of the rotor model with vibrational shape fluctuations that are adiabatically decoupled from the rotational degrees of freedom. An analysis of the states in terms of their SU(3) content shows that SU(3) is a very poor dynamical symmetry but an excellent quasi-dynamical symmetry for the model. It is argued that such quasi-dynamical symmetry can be expected for any Hamiltonian that reproduces the observed low-energy properties of a well-deformed nucleus, whenever the latter are well-described by the nuclear rotor model.

03.65.Fd
05.70.Fh
21.60.Fw
21.60.Ev
Dynamical symmetry
Quasi-dynamical symmetry
Symplectic model
SU(3)
Shell model
Nuclear Structure

References(38)

Figures(0)

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