Nature of Isoscalar Dipole Resonances in Heavy Nuclei

V. I. Abrosimov; O. I. Davydovska

doi:10.15407/ujpe63.12.1043

Nature of Isoscalar Dipole Resonances in Heavy Nuclei

Authors

V. I. Abrosimov Institute for Nuclear Research, Nat. Acad. Sci. of Ukraine
O. I. Davydovska Institute for Nuclear Research, Nat. Acad. Sci. of Ukraine

DOI:

https://doi.org/10.15407/ujpe63.12.1043

Keywords:

kinetic model, isoscalar dipole nuclear response, velocity field, vortex and compression modes

Abstract

The isoscalar dipole nuclear response reveals low- and high-energy resonances. The nature of isoscalar dipole resonances in heavy spherical nuclei is studied, by using a translation-invariant kinetic model of small oscillations of finite Fermi systems. Calculations of the velocity field at the centroid energy show a pure vortex character of the low-energy isoscalar dipole resonance in spherical nuclei and confirm the anisotropic compression character of the high-energy one. The evolution of the velocity field as a function of the excitation energy of the nucleus within the resonance width is studied. It is found that the low-energy isoscalar dipole resonance retains a vortex character, while with this collective excitation also involves a compression, as the energy increases. The high-energy resonance keeps the compression character with a change in the excitation energy within the resonance width, but the compression-expansion region of the velocity field related to this resonance shifts inside the nucleus.

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Published

2018-12-09

How to Cite

Abrosimov, V. I., & Davydovska, O. I. (2018). Nature of Isoscalar Dipole Resonances in Heavy Nuclei. Ukrainian Journal of Physics, 63(12), 1043. https://doi.org/10.15407/ujpe63.12.1043

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Issue

Vol. 63 No. 12 (2018)

Section

Fields and elementary particles

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