On the low-energy electromagnetic dipole modes in 151,153,155Sm Nuclei

•The recently observed low-energy M1 and E1 excitations in 151,153,155Sm are theoretically investigated.•The gross features of low-lying dipole modes are satisfactorily reproduced.•The low energy spectrum is shown to be dominated by M1 excitations.•No evidence supporting the existence of the spin-sc...

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Bibliographic Details
Published in:Chinese journal of physics (Taipei) 2024-12, Vol.92, p.1158-1173
Main Authors: Tabar, E., Hoşgör, G., Yakut, H., Kemah, E., Karademirci Kömürcü, Y.
Format: Article
Language:English
Subjects:
151,153,155Sm
Electromagnetic dipole
Low-lying dipole excitations
Scissors mode
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Summary:•The recently observed low-energy M1 and E1 excitations in 151,153,155Sm are theoretically investigated.•The gross features of low-lying dipole modes are satisfactorily reproduced.•The low energy spectrum is shown to be dominated by M1 excitations.•No evidence supporting the existence of the spin-scissor mode is found. The recently observed low-energy magnetic dipole (M1) and electric dipole (E1) excitations in deformed 151,153,155Sm are theoretically analysed. Rotational Invariant (RI-) and Translational-Galilean Invariant (TGI-) Quasiparticle Nuclear Model (QPNM) are used in the calculation of M1 and E1 properties, respectively. Both theories consider monopole pairing between nucleons, and the deformed Woods-Saxon potential is used as the mean-field potential. Pyatov's symmetry restoration procedure is applied in these models to eliminate the spurious modes from the intrinsic nuclear excitations. Model calculations show that although E1 transitions dominate the low-energy dipole spectra of 151,153,155Sm, many low-lying M1 transitions exist in these nuclei. It is shown that the most significant contribution to E1 and M1 excitation comes from ΔK=±1 transitions. The theory satisfactorily reproduces the gross features of low-lying dipole modes determined from the Oslo Method analysis of the experimental spectra. [Display omitted]
ISSN:0577-9073
DOI:10.1016/j.cjph.2024.10.030