The p-process in exploding rotating massive stars
Abstract
The p-process nucleosynthesis can explain proton-rich isotopes that are heavier than iron, which are observed in the Solar System, but discrepancies still persist and important questions concerning the astrophysical site(s) of the p-process remain unanswered. We investigate how the p-process operates in exploding rotating massive stars that have experienced an enhanced s-process nucleosynthesis during their life through rotational mixing. We computed 25 stellar models at a metallicity of with different initial rotation velocities and rates for the uncertain O(,)Ne reaction. The nucleosynthesis calculation, followed with a network of 737 isotopes, was coupled to stellar evolution, and the p-process nucleosynthesis was calculated in post-processing during both the final evolutionary stages and spherical explosions of various energies. In our models, the p-nuclides are mainly synthesized during the explosion, but not much during the ultimate hydrostatic burning stages. The p-process yields mostly depend on the initial number of trans-iron seeds, which in turn depend on the initial rotation. We found that the impact of rotation on the p-process is comparable to the impact of rotation on the s-process. From no to fast rotation, the s-process yields of nuclides with mass number increase by dex, and so do the p-process yields. Fast rotation with a lower O() rate significantly produces s- and p-nuclides with . Our results suggest that the contribution of core-collapse supernovae from massive stars to the solar (and Galactic) p-nuclei has been underestimated in the past, and more specifically, that the contribution from massive stars with sub-solar metallicities may even dominate. A more detailed study including stellar models with a wide range of masses and metallicities remains to be performed.
Keywords
Cite
@article{arxiv.2203.16380,
title = {The p-process in exploding rotating massive stars},
author = {A. Choplin and S. Goriely and R. Hirschi and N. Tominaga and G. Meynet},
journal= {arXiv preprint arXiv:2203.16380},
year = {2022}
}
Comments
12 pages, 13 figures, 2 tables, accepted for publication in A&A