Calculations of \(^{8}\)He+p Elastic Cross Sections Using Microscopic Optical Potential

An approach to calculate microscopic optical potential (OP) with the real part obtained by a folding procedure and with the imaginary part inherent in the high-energy approximation (HEA) is applied to study the \(^8\)He+p elastic scattering data at energies of tens of MeV/nucleon (MeV/N). The neutro...

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Bibliographic Details
Published in:arXiv.org 2009-08
Main Authors: Lukyanov, V K, Zemlyanaya, E V, Lukyanov, K V, Kadrev, D N, Antonov, A N, Gaidarov, M K, Massen, S E
Format: Article
Language:English
Subjects:
Beams (radiation)
Elastic scattering
Mathematical analysis
Proton density (concentration)
Scattering cross sections
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Summary:An approach to calculate microscopic optical potential (OP) with the real part obtained by a folding procedure and with the imaginary part inherent in the high-energy approximation (HEA) is applied to study the \(^8\)He+p elastic scattering data at energies of tens of MeV/nucleon (MeV/N). The neutron and proton density distributions obtained in different models for \(^{8}\)He are utilized in the calculations of the differential cross sections. The role of the spin-orbit potential is studied. Comparison of the calculations with the available experimental data on the elastic scattering differential cross sections at beam energies of 15.7, 26.25, 32, 66 and 73 MeV/N is performed. The problem of the ambiguities of the depths of each component of the optical potential is considered by means of the imposed physical criterion related to the known behavior of the volume integrals as functions of the incident energy. It is shown also that the role of the surface absorption is rather important, in particular for the lowest incident energies (e.g., 15.7 and 26.25 MeV/nucleon).
ISSN:2331-8422
DOI:10.48550/arxiv.0908.1008