alpha+d -> 6Li + gamma astrophysical S factor and its implications for Big Bang nucleosynthesis

The alpha+d->6Li+gamma radiative capture is studied in order to predict the Li6 primordial abundance. Within a two-body framework, the alpha particle and the deuteron are considered the structureless constituents of Li6. Five alpha+d potentials are used to solve the two-body problem: four of them are taken from the literature, only one having also a tensor component. A fifth model is here constructed in order to reproduce, besides the Li6 static properties as binding energy, magnetic dipole, and electric quadrupole moments, also the S-state asymptotic normalization coefficient (ANC). The two-body bound and scattering problem is solved with different techniques, in order to minimize the numerical uncertainty of the present results. The long-wavelength approximation is used, and therefore only the electric dipole and quadrupole operators are retained. The astrophysical S factor is found to be significantly sensitive to the ANC, but in all the cases in good agreement with the available experimental data. The theoretical uncertainty has been estimated of the order of few percent when the potentials which reproduce the ANC are considered, but increases up to ~20% when all five potential models are retained. The effect of this S-factor prediction on the Li6 primordial abundance is studied, using the public code PArthENoPE. For the five models considered here we find Li6/H=(0.9-1.8)±10^{-14}, with the baryon density parameter in the 3-sigma range of Planck 2015 analysis, Omegab h^2=0.02226±0.00023.