Once more about astrophysical S factor for the α + d 6 Li + γ reaction

Abstract

Recently to study the radiative capture α + d 6 Li + γ process a new measurement of the 6 Li( A\,150\,MeV) dissociation in the field of 208 Pb has been reported in [F. Hammache et al. Phys. Rev C 82, 065803 (2010)]. However, the dominance of the nuclear breakup over the Coulomb one prevented from obtaining the information about the α + d 6 Li + γ process from the breakup data. The astrophysical S24(E) factor has been calculated within the α-d two-body potential model with potentials determined from the fits to the α-d elastic scattering phase shifts. However, the scattering phase shift itself doesn't provide a unique α-d bound state potential, which is the most crucial input when calculating the S24(E) astrophysical factor at astrophysical energies. In this work we emphasize an important role of the asymptotic normalization coefficient (ANC) for 6 Li α + d, which controls the overall normalization of the peripheral α + d 6 Li + γ process and is determined by the adopted α-d bound state potential. We demonstrate that the ANC previously determined from the α-d elastic scattering s-wave phase shift in [Blokhintsev et. al Phys. Rev. C 48, 2390 (1993)] gives S24(E), which is at low energies about 38% lower than the one reported in [F. Hammache et al. Phys. Rev C 82, 065803 (2010)]. We recalculate also the reaction rates, which are also lower than those obtained in [F. Hammache et al. Phys. Rev C 82, 065803 (2010)].