Exactly separable version of the Bohr Hamiltonian with the Davidson potential

Bonatsos, Dennis; McCutchan, E. A.; Minkov, N.; Casten, R. F.; Yotov, P.; Lenis, D.; Petrellis, D.; Yigitoglu, I.

doi:10.1103/physrevc.76.064312

Cited by 96 publications

(108 citation statements)

References 54 publications

(168 reference statements)

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“…1, are similar for small values of β, where the 1/β 2 term dominates in both cases, but they differ substantially at large values of β, where the tails of the wave functions behave as e −β 2 /2 [33] and e −β/2 [31,32] (iii) The DDM Bohr Hamiltonian with the Davidson potential works well for deformed nuclei, but fails in describing the nuclei lying at the critical point between the spherical and deformed regions [34,35], known to be examples of the X(5) critical point symmetry [36]. It is interesting to examine if the DDM Bohr Hamiltonian with the Kratzer potential overcomes this drawback.…”

Section: Introductionmentioning

confidence: 89%

“…(B4) of Ref. [33], in which the square of the radial integral appears. The radial integral for γ-unstable nuclei is given in Eq.…”

Section: B(e2)smentioning

confidence: 94%

“…The same set of experimental data for spectra and B(E2) transition rates has been used as in the cases of the Deformation Dependent Mass (DDM) Davidson model [17], the Exactly Separable Davidson (ESD) model [33], and the Morse potential [48,49], in order to facilitate comparisons of the various models among themselves and to the data. The theoretical predictions for the levels are obtained from Eq.…”

Section: A Spectra Of γ-Unstable Nucleimentioning

confidence: 99%

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Bohr Hamiltonian with a deformation-dependent mass term for the Kratzer potential

et al. 2013

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The Deformation Dependent Mass (DDM) Kratzer model is constructed by considering the Kratzer potential in a Bohr Hamiltonian, in which the mass is allowed to depend on the nuclear deformation, and solving it by using techniques of supersymmetric quantum mechanics (SUSYQM), involving a deformed shape invariance condition. Analytical expressions for spectra and wave functions are derived for separable potentials in the cases of γ-unstable nuclei, axially symmetric prolate deformed nuclei, and triaxial nuclei, implementing the usual approximations in each case. Spectra and B(E2) transition rates are compared to experimental data. The dependence of the mass on the deformation, dictated by SUSYQM for the potential used, moderates the increase of the moment of inertia with deformation, removing a main drawback of the model.

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Section: Introductionmentioning

confidence: 89%

“…(B4) of Ref. [33], in which the square of the radial integral appears. The radial integral for γ-unstable nuclei is given in Eq.…”

Section: B(e2)smentioning

confidence: 94%

Section: A Spectra Of γ-Unstable Nucleimentioning

confidence: 99%

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Bohr Hamiltonian with a deformation-dependent mass term for the Kratzer potential

et al. 2013

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“…Many approaches have been developed [48][49][50][51][52][53][54][55][56][57][58][59][60][61][62], mainly by Bonatsos and collaborators, that simulate critical point nuclei, or the evolution of structure near the critical point. We will not discuss these in detail here-they have been reviewed recently [63,64].…”

Section: Now Consider the Yrast Energies Of A Harmonic Vibratormentioning

confidence: 99%

Quantum phase transitions and structural evolution in nuclei

Casten

2009

Progress in Particle and Nuclear Physics

100

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“…In Refs. [44,45] the authors treated exactly separable versions of the Davidson potential and of the X(5) potential, respectively. Finally, in Ref.…”

Section: Introductionmentioning

confidence: 99%

Relationship between X(5) models and the interacting boson model

García‐Ramos

Arias

2010

Phys. Rev. C

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The connections between the X(5) models [the original X(5) using an infinite square well, X(5)-β 8 , X(5)-β 6 , X(5)-β 4 , and X(5)-β 2 ], based on particular solutions of the geometrical Bohr Hamiltonian with harmonic potential in the γ degree of freedom, and the interacting boson model (IBM) are explored. This work is the natural extension of the work presented in García-Ramos and Arias, Phys. Rev. C 77, 054307 (2008) for the E(5) models. For that purpose, a quite general one-and two-body IBM Hamiltonian is used and a numerical fit to the different X(5) model energies is performed; then the obtained wave functions are used to calculate B(E2) transition rates. It is shown that within the IBM one can reproduce well the results for energies and B(E2) transition rates obtained with all these X(5) models, although the agreement is not so impressive as for the E(5) models. From the fitted IBM parameters the corresponding energy surface can be extracted and, surprisingly, only the X(5) case corresponds in the moderately large N limit to an energy surface very close to the one expected for a critical point, whereas the rest of models are situated a little further away.

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Exactly separable version of the Bohr Hamiltonian with the Davidson potential

Cited by 96 publications

References 54 publications

Bohr Hamiltonian with a deformation-dependent mass term for the Kratzer potential

Bohr Hamiltonian with a deformation-dependent mass term for the Kratzer potential

Quantum phase transitions and structural evolution in nuclei

Relationship between X(5) models and the interacting boson model

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