A. El Batoul scite author profile

A prolate γ-rigid regime of the Bohr-Mottelson Hamiltonian within the minimal length formalism, involving an infinite square well like potential in β collective shape variable, is developed and used to describe the spectra of a variety of vibrational-like nuclei. The effect of the minimal length on the energy spectrum and the wave function is duly investigated. Numerical calculations are performed for some nuclei revealing a qualitative agreement with the available experimental data.

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Electric quadrupole transitions of the Bohr Hamiltonian with Manning–Rosen potential

Chabab

Batoul

Lahbas

et al. 2016

Nuclear Physics A

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Analytical expressions of the wave functions are derived for a Bohr Hamiltonian with the Manning-Rosen potential in the cases of γ-unstable nuclei and axially symmetric prolate deformed ones with γ ≈ 0. By exploiting the results we have obtained in a recent work on the same theme Ref.[1], we have calculated the B(E2) transition rates for 34 γ-unstable and 38 rotational nuclei and compared to experimental data, revealing a qualitative agreement with the experiment and phase transitions within the ground state band and showing also that the Manning-Rosen potential is more appropriate for such calculations than other potentials.

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Collective motion in prolate γ-rigid nuclei within minimal length concept via a quantum perturbation method

et al. 2018

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Based on the minimal length concept, inspired by Heisenberg algebra, a closed analytical formula is derived for the energy spectrum of the prolate γ-rigid Bohr-Mottelson Hamiltonian of nuclei, within a quantum perturbation method (QPM), by considering a scaled Davidson potential in β shape variable. In the resulting solution, called X(3)-D-ML, the ground state and the first β-band are all studied as a function of the free parameters. The fact of introducing the minimal length concept with a QPM makes the model very flexible and a powerful approach to describe nuclear collective excitations of a variety of vibrational-like nuclei. The introduction of scaling parameters in the Davidson potential enables us to get a physical minimum of this latter in comparison with previous works. The analysis of the corrected wave function, as well as the probability density distribution, shows that the minimal length parameter has a physical upper bound limit.

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Publisher’s Note: “Exact solutions of deformed Schrödinger equation with a class of non-central physical potentials” [J. Math. Phys. 56, 062111 (2015)]

Chabab

Batoul

Oulne

2015

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Nuclear shape phase transition within a conjunction ofγ-rigid andγ-stable collective behaviors in deformation-dependent mass formalism

Chabab¹,

Batoul²,

Lahbas³

et al. 2016

J. Phys. G: Nucl. Part. Phys.

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In this paper, we present a theoretical study of a conjonction of γ-rigid and γ-stable collective motions in critical point symmetries of the phase transitions from spherical to deformed shapes of nuclei using exactly separable version of the Bohr Hamiltonian with deformation-dependent mass term. The deformation-dependent mass is applied simultaneously to γ-rigid and γ-stable parts of this famous collective Hamiltonian. Moreover, the β part of the problem is described by means of Davidson potential, while the γ-angular part corresponding to axially symmetric shapes is treated by a Harmonic Osillator potential. The energy eigenvalues and normalized eigenfunctions of the problem are obtained in compact forms by making use of the asymptotic iteration method. The combined effect of the deformation-dependent mass and rigidity as well as harmonic oscillator stiffness parameters on the energy spectrum and wave functions is duly investigated. Also, the electric quadrupole transition ratios and energy sprectrum of some γ-stable and prolate nuclei are calculated and compared with the experimental data as well as with other theoretical models.

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A. El Batoul

On γ -rigid regime of the Bohr–Mottelson Hamiltonian in the presence of a minimal length

Electric quadrupole transitions of the Bohr Hamiltonian with Manning–Rosen potential

Collective motion in prolate γ-rigid nuclei within minimal length concept via a quantum perturbation method

Publisher’s Note: “Exact solutions of deformed Schrödinger equation with a class of non-central physical potentials” [J. Math. Phys. 56, 062111 (2015)]

Nuclear shape phase transition within a conjunction ofγ-rigid andγ-stable collective behaviors in deformation-dependent mass formalism

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