Impact of Nuclear Reaction Uncertainties on AGB Nucleosynthesis Models

TL;DR

This study investigates how uncertainties in key nuclear reaction rates affect the synthesis of elements in low-mass AGB stars, highlighting their impact on isotopic ratios near s-process branch points.

Contribution

It provides a detailed analysis of the effects of reaction rate uncertainties on AGB nucleosynthesis, especially near branching points, using updated models and focusing on the main s-process component.

Findings

Uncertainties in 13C(alpha, n)16O significantly affect 86Kr and 87Rb production.

Variations in 22Ne(alpha, n)25Mg rates within a factor of 2 still reproduce solar s-only isotopes.

Reaction rate uncertainties influence isotopic ratios near s-process branchings.

Abstract

Asymptotic giant branch (AGB) stars with low initial mass (1 - 3 Msun) are responsible for the production of neutron-capture elements through the main s-process (main slow neutron capture process). The major neutron source is 13C(alpha, n)16O, which burns radiatively during the interpulse periods at about 8 keV and produces a rather low neutron density (10^7 n/cm^3). The second neutron source 22Ne(alpha, n)25Mg, partially activated during the convective thermal pulses when the energy reaches about 23 keV, gives rise to a small neutron exposure but a peaked neutron density (Nn(peak) > 10^11 n/cm^3). At metallicities close to solar, it does not substantially change the final s-process abundances, but mainly affects the isotopic ratios near s-path branchings sensitive to the neutron density. We examine the effect of the present uncertainties of the two neutron sources operating in AGB stars, as well as the competition with the 22Ne(alpha, gamma)26Mg reaction. The analysis is carried out on AGB the main-s process component (reproduced by an average between M(AGB; ini) = 1.5 and 3 Msun at half solar metallicity, see Arlandini et al. 1999), using a set of updated nucleosynthesis models. Major effects are seen close to the branching points. In particular, 13C(alpha, n)16O mainly affects 86Kr and 87Rb owing to the branching at 85Kr, while small variations are shown for heavy isotopes by decreasing or increasing our adopted rate by a factor of 2 - 3. By changing our 22Ne(alpha, n)25Mg rate within a factor of 2, a plausible reproduction of solar s-only isotopes is still obtained. We provide a general overview of the major consequences of these variations on the s-path. A complete description of each branching will be presented in Bisterzo et al., in preparation.