Impacts of the $^{16}$O($^{16}$O, n)$^{31}$S reaction rate on the evolution and nucleosynthesis in Pop III massive stars

TL;DR

This study examines how varying the $^{16}$O($^{16}$O, n)$^{31}$S reaction rate influences the evolution and nucleosynthesis in Pop III stars, revealing that increased rates enhance neutron-rich isotope production and align model predictions with observed metal-poor star abundances.

Contribution

It provides the first systematic analysis of the impact of the $^{16}$O($^{16}$O, n)$^{31}$S reaction rate on Pop III star evolution and nucleosynthesis, highlighting its significance for potassium production.

Findings

Higher reaction rates lead to earlier and longer oxygen burning phases.

Enhanced rates increase neutron-rich isotope synthesis, especially $^{31}$P and $^{39}$K.

Predicted potassium yields match observations for extremely metal-poor stars.

Abstract

We first present a systematic investigation into the effect of the $^{16}$O($^{16}$O, n)$^{31}$S reaction rate on the evolution and nucleosynthesis of Population III (Pop III) stars. We simulate the evolution of a 15 M$_\odot$ Pop III star from the zero-age main sequence through to core collapse, while varying the $^{16}$O($^{16}$O, n)$^{31}$S reaction rate by factors of 0.1, 1, and 10. Our results demonstrate that increasing this reaction rate prompts earlier onset and extended duration of core oxygen burning at lower temperatures and densities. A higher reaction rate also increases neutron excess in OSi-rich layers, thereby promoting the synthesis of neutron-rich isotopes, particularly $^{31}$P and $^{39}$K. Most notably, the K yield is enhanced by a factor of 6.4. For a tenfold enhancement of the $^{16}$O($^{16}$O, n)$^{31}$S rate, the predicted [K/Ca] and [K/Fe] values from presupernova models reach 0.29 and 0.22 dex, respectively-values that are consistent with the most recent observational data for extremely metal-poor stars. These findings hold promise as a potential new solution to the problem of potassium underproduction and offer a valuable theoretical reference and motivation for subsequent measurements of oxygen fusion reaction rate.