Production Cross-Section of \(\gamma \)-Rays from (p,p\(^\prime \gamma \)) Reactions: Measurements and Theoretical Analysis

Abstract

This paper reviews our work on the measurements of absolute production cross sections of \(\gamma \)-rays from the (p,p\(^{\prime }\gamma \)) reactions on \(^{12}\)C and \(^{16}\)O. The measurements cover a range of 8–16 MeV for the incident proton beam. The angular distributions of the \(\gamma \)-rays have been measured. A detailed phenomenological analysis within the framework of optical model formalism has been carried out to reproduce the experimental data. The existing global set of elastic, polarization and total reaction data for protons and neutrons have been used to generate the optical model potential. The nuclear structure effects have been included in the calculations by considering the roles of coupling of the low-lying states, the presence of resonances and nuclear deformations. The potentials so generated have been used to calculate the differential and total cross sections for both (p,p\(^\prime \)) and (p,p\(^\prime \gamma \)) reactions. The results of the analysis are in good agreement with the measured data for the observed \(\gamma \)-rays. However, discrepancies still exist in reproducing the finer details of the cross sections. The existing discrepancies between our phenomenological analysis and the experimental data demonstrate the rather complex roles of channel couplings, resonances in the compound nuclear system and target deformation. The significant contribution of nuclear structure effects in light mass nucleus like \(^{12}\)C and \(^{16}\)O, leads to an apparent loss of predictive power of the theoretical calculation for low-energy region (less than 10 MeV) of the projectile energy.