V. V. Parkar

TL;DR: In this article, a detailed analysis of the angular distribution using coupled channels Born approximation calculations has provided clear evidence that the observed α + d events arise from a two-step process, i.e., direct transfer to the 2.186 MeV (3 + ) resonance in the α+ d continuum of 6Li followed by breakup, and are not due to final state interaction effects.

TL;DR: In this article, the effect of coupling of both the projectile and target excitations on the above quantities has been investigated, and the complete fusion cross sections, especially at above-barrier energies, have been found to be suppressed by ($20.5$) compared to the ones predicted by the coupled-channels calculations that do not include the couplings to the projectile continuum, indicating the loss of flux from the entrance channel before fusion.

TL;DR: In this article, the authors showed that the complete fusion excitation function at near barrier energies can be suppressed by 32% in the case of the Coulomb barrier penetration model with strongly bound projectiles forming a similar compound nucleus.

TL;DR: In this article, the role played by the cluster structures of 7Li in understanding the reaction dynamics at energies around the Coulomb barrier was demonstrated, and it was inferred that massive transfer was the dominant mechanism for He 6 + p and He 5 + d configurations.

TL;DR: In this paper, complete and incomplete fusion cross sections at above-barrier energies are suppressed by $~$34% compared to coupled-channel calculations, and the extent of suppression is correlated with the separation energies of the projectiles.