This work presents a combined experimental and theoretical investigation of the nuclear reaction ^6Li + ^12C at a laboratory energy of 68 MeV. The reaction products are identified via the standard ΔE-E technique. Angular distributions are constructed for the elastic, inelastic, and deuteron transfer channels by detecting emitted particles -- ^6Li and α. Elastic and inelastic scattering of ^6Li on ^12C are analyzed using both the Optical Model and Coupled channels approaches, with the interaction described by a double-folding potential. This potential is calculated based on the three-body wave function of ^6Li. Pronounced coupled-channel effects are observed, which modify the potential and allow accurate reproduction of the experimental cross sections. The resulting polarized potentials provide a more precise description of the initial-state interaction for further reaction modelling. The deuteron transfer channel, ^12C (^6Li, α) ^14N, is studied using the Coupled Reaction Channels method. The coupling between the transfer and elastic channels is implemented using the three-body wave function of ^6Li. As an alternative, a regular wave function constructed with a phenomenological Woods-Saxon potential is also employed. Comparison between the calculated differential cross sections and experimental data reveals a more complex and nuanced reaction mechanism, which supports the cluster structure of ^6Li.
Уразбеков et al. (Mon,) studied this question.
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