Decay properties of 22Ne + α resonances and their impact on s-process nucleosynthesis

Abstract

The astrophysical s-process is one of the two main processes forming elements heavier than iron. A key outstanding uncertainty surrounding s-process nucleosynthesis is the neutron flux generated by the 22Ne(α, n)25Mg reaction during the He-core and C-shell burning phases of massive stars. This reaction, as well as the competing 22Ne(α, γ)26Mg reaction, is not well constrained in the important temperature regime from 0.2--0.4~GK, owing to uncertainties in the nuclear properties of resonances lying within the Gamow window. To address these uncertainties, we have performed a new measurement of the 22Ne(6Li, d)26Mg reaction in inverse kinematics, detecting the outgoing deuterons and 25,26Mg recoils in coincidence. We have established a new n / γ decay branching ratio of 1.14(26) for the key Ex = 11.32 MeV resonance in 26Mg, which results in a new (α, n) strength for this resonance of 42(11)~μeV when combined with the well-established (α, γ) strength of this resonance. We have also determined new upper limits on the α partial widths of neutron-unbound resonances at Ex = 11.112, 11.163, 11.169, and 11.171 MeV. Monte-Carlo calculations of the stellar 22Ne(α, n)25Mg and 22Ne(α, γ)26Mg rates, which incorporate these results, indicate that both rates are substantially lower than previously thought in the temperature range from 0.2--0.4~GK.