In the elastic scattering angular distributions of nuclei, the secondary rainbow manifests itself as an extra maximum (accompanied with a minimum as well) in the darkside of the primary rainbow. This phenomenon was first observed in the elastic scattering of Formula: see textO+Formula: see textC at around 300Formula: see textMeV. It is believed to be generated by the coupling to the first 2Formula: see text excitation of Formula: see textC and influenced by the couplings to other inelastic scattering channels. In this work, the optical potentials with a spline real part were utilized in the optical model analyses of the elastic scattering data of Formula: see textO+Formula: see textC at 300Formula: see textMeV and 330Formula: see textMeV. The spline real potentials were obtained by performing the data fitting starting from the phenomenological Woods–Saxon form and the double folding one, respectively. Through this approach, the secondary rainbow patterns of the two systems were reproduced well. The obtained spline real potentials exhibit an evident additional refraction (a potential pocket) at around Formula: see textFormula: see textfm and show a preference to the shallow central depth. The semiclassical analyses were performed to learn the physical meaning of these obtained optical potentials. According to the nearside/farside decomposition, this secondary rainbow pattern was shown as the result of the farside scattering. In the deflection functions, a new minimum appears apart from the primary rainbow one, of which the former was proved to be related to the secondary rainbow maximum in the angular distribution. The potential pocket around Formula: see textFormula: see textfm in the real potential was found responsible for the generation of the secondary rainbow pattern. However, the additional refraction caused by this potential pocket might not be associated with the Airy pattern. The present physical picture of the nuclear primary/secondary rainbow pattern is a two-refraction process originating from the non-monotonic repulsive-attractive real potential. Hence, the secondary rainbow pattern in the angular distribution corresponds to a complicated interference of the farside trajectories which distorts the original Airy oscillation pattern. Besides, for the phenomenological analysis of this pattern, a potential ambiguity was also found in the undulations of the real potential.
Liyuan Hu (Tue,) studied this question.
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