Clustering effects in the 6Li(p,3He)4He reaction at astrophysical energies

Abstract

Background: The understanding of nuclear reactions between light nuclei at energies below the Coulomb barrier is important for several astrophysical processes, but their study poses experimental and theoretical challenges. At sufficiently low energies, the electrons surrounding the interacting ions affect the scattering process. Moreover, the clustered structure of some of these nuclei may play a relevant role on the reaction observables. Purpose: In this article, we focus on a theoretical investigation of the role of clustered configurations of 6Li in reactions of astrophysical interest. Methods: The 6Li(p,3He)4He reaction cross section is described considering both the direct transfer of a deuteron as a single point-like particle in Distorted Wave Born Approximation (DWBA), and the transfer of a neutron and a proton in second-order DWBA. A number of two- and three-cluster structure models for 6Li are compared. Results: Within the two-cluster structure model, we explore the impact of the deformed components in the 6Li wave-function on the reaction of interest. Within the three-cluster structure model, we gauge the degree of α-d clustering and explicitly probe its role on specific features of the reaction cross section. We compare the energy trend of the astrophysical S factor deduced in each case. Conclusions: Clustered 6Li configurations lead in general to a significant enhancement of the astrophysical factor in the energy region under study. This effect only originates from clustering, whereas static deformations of the ground-state configuration play a negligible role at very low energies.