Large-angle 6Li + 28Si elastic and inelastic scattering at 27 and 34 MeV

Abstract

Elastic and inelastic scattering data extending to θ c.m ≈ 175° are reported for 6Li + 28Si at 27 and 34 MeV. Optical model analyses of the elastic data were made using a variety of real potential forms. The large-angle data cannot be fitted with a Woods-Saxon real potential, but are well described by Woods-Saxon squared, double-folded or Fourier-Bessel potentials. The real potential is the same at both energies, but the imaginary potential is weaker at 27 MeV. The inelastic data were analyzed using the DWBA and coupled channels techniques with folded real form factors and deformed Woods-Saxon imaginary potentials, with the deformations taken from electron scattering. The 2 + state was fitted well at both energies with the DWBA, while the prediction decreased too rapidly at large angles for the 4 + state. The large-angle 4 + data were better described when two-step excitations were included in the coupled-channels calculations. The forward-angle 2 + data are sensitive to the interference between Coulomb and nuclear scattering and show that the nuclear and Coulomb deformation parameters β 2 are equal for this transition.