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

TL;DR

This study models rotating massive stars to understand their production of short-lived radioactive isotopes and their contribution to the early Solar System's composition.

Contribution

It provides detailed wind yield predictions for radioactive isotopes from rotating massive stars up to core-collapse, extending previous binary star focus.

Findings

Models with initial masses ≥40M☉ match early Solar System $^{26}$Al and $^{41}$Ca abundances.

Only the most massive models (≥60M☉) produce enough $^{36}$Cl to match Solar System data.

Wind models do not produce significant $^{60}$Fe, aligning with observations.

Abstract

Radioactive nuclei were present in the early Solar System, as inferred from analysis of meteorites. Many are produced in massive stars, either during their lives or their final explosions. In the first paper in this series (Brinkman et al. 2019), we focused on the production of $^{26}$Al in massive binaries. Here, we focus on the production of another two short-lived radioactive nuclei, $^{36}$Cl and $^{41}$Ca, and the comparison to the early Solar System data. We used the MESA stellar evolution code with an extended nuclear network and computed massive (10-80 M$ _{\odot} $), rotating (with initial velocities of 150 and 300 km/s) and non-rotating single stars at solar metallicity (Z=0.014) up to the onset of core collapse. We present the wind yields for the radioactive isotopes $^{26}$Al, $^{36}$Cl, and $^{41}$Ca, and the stable isotopes $^{19}$F and $^{20}$Ne. In relation to the stable isotopes, we find that only the most massive models, $\geq$ 60M$_{\odot}$ and $\geq$ 40M$_{\odot}$ give positive $^{19}$F and $^{20}$Ne yields, respectively, depending on the initial rotation rate. In relation to the radioactive isotopes, we find that the early Solar System abundances of $^{26}$Al and $^{41}$Ca can be matched with by models with initial masses $\geq$40M$_{\odot}$, while $^{36}$Cl is matched only by our most massive models, $\geq$60M$_{\odot}$. $^{60}$Fe is not significantly produced by any wind model, as required by the observations. Therefore, massive star winds are a favoured candidate for the origin of the very short-lived $^{26}$Al, $^{36}$Cl, and $^{41}$Ca in the early Solar System.