Low-energy 3He(α,γ)7Be reaction within the Skyrme potential framework

Abstract

Background: The 3He(α,γ)7Be reaction plays a crucial role in the proton-proton chain and Big Bang nucleosynthesis, affecting solar neutrino fluxes and primordial element abundances. Experimental data at astrophysical energies remain uncertain due to the extremely low cross sections. \\ Purpose: This work uses a microscopic potential-model approach to construct the 3He+α potential from the nucleon+α interaction, aiming to describe low-energy elastic scattering and to calculate the astrophysical S factor of the 3He(α,γ)7Be reaction. \\ Method: The nucleon-nucleus potential is derived from self-consistent Skyrme Hartree-Fock (HF) calculations extended to the continuum. The 3He+α potential is then obtained by folding the HF potential with the 3He density. A small number of scaling parameters is constrained by elastic-scattering data.\\ Result: The scaled Skyrme HF potential and folded potential simultaneously reproduce the low-energy p+α and 3He+α s-wave phase shifts, respectively. The calculated astrophysical S factor of 3He(α,γ)7Be shows good agreement with experimental data, yielding the recommended value S34(0) = 0.610 0.024~keV~b. A moderate sensitivity of S34(0) to the choice of projectile density is also observed in the folding procedure. \\ Conclusion: The Skyrme HF-based potential provides a unified and predictive microscopic framework for describing both elastic scattering and radiative capture in light nuclei.