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Solutions of the Bohr hamiltonian, a compendium

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abstract

The Bohr hamiltonian, also called collective hamiltonian, is one of the cornerstone of nuclear physics and a wealth of solutions (analytic or approximated) of the associated eigenvalue equation have been proposed over more than half a century (confining ourselves to the quadrupole degree of freedom). Each particular solution is associated with a peculiar form for the $V(\beta,\gamma)$ potential. The large number and the different details of the mathematical derivation of these solutions, as well as their increased and renewed importance for nuclear structure and spectroscopy, demand a thorough discussion. It is the aim of the present monograph to present in detail all the known solutions in $\gamma-$unstable and $\gamma-$stable cases, in a taxonomic and didactical way. In pursuing this task we especially stressed the mathematical side leaving the discussion of the physics to already published comprehensive material. The paper contains also a new approximate solution for the linear potential, and a new solution for prolate and oblate soft axial rotors, as well as some new formulae and comments, and an appendix on the analysis of a few interesting numerical sequences appearing in this context. The quasi-dynamical SO(2) symmetry is proposed in connection with the labeling of bands in triaxial nuclei.

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nucl-th 1

years

2026 1

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UNVERDICTED 1

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The Confined beta-Soft rotor model in rare-earth nuclei

nucl-th · 2026-06-10 · unverdicted · novelty 2.0

Application of the CBS rotor model to rare-earth nuclei yields calculated energies and transition rates compared against experimental data with some unmeasured predictions.

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  • The Confined beta-Soft rotor model in rare-earth nuclei nucl-th · 2026-06-10 · unverdicted · none · ref 18 · internal anchor

    Application of the CBS rotor model to rare-earth nuclei yields calculated energies and transition rates compared against experimental data with some unmeasured predictions.