The continuum-discritized coupled channel method and the glauber model are applied for the description of deuteron elastic breakup and the stripping processes, respectively. Combined with the conventional two-component exciton model for pre-equilibrium processes and the Hauser-Feshbach theory for compound process, an approach based on models is proposed to analyze the inclusive proton energy spectra of a deuteron-induced reaction. The contributions from each process to the energy spectra of the 58 Ni(d,xp) reaction are quantitatively given. The results show that this approach is able to reasonably reproduce the experimental data of the double differential cross sections, energy spectra and cross sections, although further improvements are needed.
Articles you may be interested inA Microscopic semi-classical model of nucleon-induced pre-equilibrium reactions AIP Conf.Abstract. Nucleon-induced cross sections on magnesium isotopes, 24 25 26 Mg, and silicon isotopes, 28 29 30 Si, were evaluated for energies up to 3 GeV. Evaluation of nucleon-scattering cross sections was performed by a consistent analysis of nuclearlevel structure and nucleon-scattering data using a unified framework of a soft-rotator model and coupled-channel approach. The scattering cross sections for silicon isotopes were re-analyzed based on two new considerations. First the silicon isotopes were assumed to be deformed nuclei having oblate shapes, second the more sophisticated form of optical-potential energy dependence was used. The evaluation of the particle emissions was performed by using a nuclear-model code system consisting of the GNASH code up to 150 MeV and the JQMD code above 150 MeV. The present results were compared with available experimental data and the LA150 evaluation.
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