Aluminium-26 from massive binary stars III. Binary stars up to core-collapse and their impact on the early Solar System

Abstract

Many of the short-lived radioactive nuclei that were present in the early Solar System can be produced in massive stars. In the first paper in this series (Brinkman et al. 2019), we focused on the production of 26Al in massive binaries. In our second paper (Brinkman et al. 2021), we considered rotating single stars, two more short-lived radioactive nuclei, 36Cl and 41Ca, and the comparison to the early Solar System data. In this work, we update our previous conclusions by further considering the impact of binary interactions. We used the MESA stellar evolution code with an extended nuclear network to compute massive (10-80 M ), binary stars at various initial periods and solar metallicity (Z=0.014), up to the onset of core collapse. The early Solar System abundances of 26Al and 41Ca can be matched self-consistently by models with initial masses ≥25 M, while models with initial primary masses ≥35 M can also match 36Cl. Almost none of the models provide positive net yields for 19F, while for 22Ne the net yields are positive from 30 M and higher. This leads to an increase by a factor of approximately 4 in the amount of 22Ne produced by a stellar population of binary stars, relative to single stars. Also, besides the impact on the stellar yields, our 10 M primary star undergoing Case A mass-transfer ends its life as a white dwarf instead of as a core-collapse supernova. This demonstrates that binary interactions can also strongly impact the evolution of stars close to the supernova boundary.