Modeling alpha-nucleus elastic scattering using a velocity-dependent optical model
Abstract
We performed a least-square fit analysis to reproduce the elastic angular distributions for scattering on various nuclei form C to Pb for incident energies in the range 18 - 70 MeV using a velocity-dependent optical model. The model reproduced the experimental data well including the enhanced angular distributions in the large-angle scattering region, which is commonly known as the anomalous large angle scattering (ALAS). Our best-fit potential parameters are linear functions of incident energy. Although the ALAS effect is not present in the case of scattering on the intermediate Ni and heavy Pb nuclei, we considered these nuclei to demonstrate the effectiveness of the VDOM in describing the angular distributions for scattering on various light, intermediate and heavy nuclei. For scattering on Ca, we compared our results to two previous works that adopted the conventional optical model. One model reproduced the data better at low energies, while the other performed better at high energies. In contrast, the velocity-dependent model of this work described the data across the considered angular range.
Cite
@article{arxiv.2310.11816,
title = {Modeling alpha-nucleus elastic scattering using a velocity-dependent optical model},
author = {A. Saleh and M. I. Jaghoub},
journal= {arXiv preprint arXiv:2310.11816},
year = {2024}
}
Comments
22 pages, 7 figures