New \textsl{s}-process Mechanism in Rapidly-Rotating Massive Pop II Stars

TL;DR

This paper introduces a new s-process mechanism in rapidly rotating massive metal-poor stars, showing they can produce heavy elements up to Bi and explaining early s-process enrichment in the universe.

Contribution

It presents a novel s-process mechanism driven by rotation-induced mixing in massive stars, highlighting their role as early sites for heavy element synthesis.

Findings

Rapid rotation leads to quasi-chemically-homogeneous evolution.

Neutron production occurs via primary $^{13}$C during core He burning.

Stars can produce elements up to Bi, explaining early s-process enrichment.

Abstract

We report a new mechanism for the \textsl{s} in rotating massive metal-poor stars. Our models show that above a critical rotation speed, such stars evolve in a quasi-chemically-homogeneous fashion, which gives rise to a prolific \textsl{s}-process. Rotation-induced mixing results in primary production of $^{13}$C, which subsequently makes neutrons via $^{13}\mathrm{C}(\alpha,\mathrm{n})^{16}\mathrm{O}$ during core He burning. Neutron capture can last up to $\sim 10^{13}\,\mathrm{s}$ ($\sim 3\times 10^{5}$~yr) with the peak central neutron density ranging from $\sim10^7$ to $10^{8}\,\mathrm{cm}^{-3}$. Depending on the rotation speed and the mass loss rate, a strong \textsl{s} can occur with production of elements up to Bi for progenitors with initial metallicities of $[Z]\lesssim -1.5$. This result suggests that rapidly-rotating massive metal-poor stars are likely the first site for the main \textsl{s}-process. We find that these stars can potentially explain the early onset of the \textsl{s}-process and some of the carbon-enhanced metal-poor (CEMP-\textsl{s} and CEMP-\textsl{r/s}) stars with strong enrichment attributed to the \textsl{s} or a mixture of the \textsl{r}-process and the \textsl{s}-process.