Dirac Coupled Channel Analyses of Proton Inelastic Scattering from $^{40}$Ar Nucleus

TL;DR

This paper analyzes 0.8 GeV proton inelastic scattering from $^{40}$Ar using a relativistic Dirac coupled channel model, highlighting the importance of multistep processes and comparing results with nonrelativistic approaches.

Contribution

It introduces a relativistic Dirac coupled channel analysis for $^{40}$Ar, incorporating multistep excitations and phenomenological parameter fitting, improving agreement with experimental data.

Findings

Good agreement with experimental differential cross sections.

Multistep excitation via the second $2^+$ state is significant.

Relativistic model results compare favorably with nonrelativistic calculations.

Abstract

0.8 GeV proton inelastic scatterings from $^{40}$Ar nucleus are analyzed using an optical potential model in the Dirac coupled channel formalism. A rotational collective model is used to obtain the transition optical potentials for the low lying excited states of the rotational band. The optical potential parameters of a Woods-Saxon shape and the deformation parameters of the excited states are searched phenomenologically to reproduce the experimental differential cross-section data by using the sequential iteration method. The effect of a multistep process is investigated by including the channel coupling between two excited states in addition to the couplings between the ground state and the excited states. The calculated deformation parameters of the excited states are compared with those obtained by using the nonrelativistic calculations. The results of the Dirac coupled channel calculations are found to show pretty good agreements with the experimental data of the ground state and the low-lying excited states. The multistep excitation process via the channel coupling with the second $2^+$ state is found to be important for the excitation of the $4^+$ state at the inelastic scatterings from the deformed nucleus, $^{40}$Ar.