Role of core-collapse supernovae in explaining Solar System abundances of p nuclides

TL;DR

This study models the contribution of core-collapse supernovae to the production of p nuclides in the Galaxy, revealing their limited role at solar metallicity and highlighting the need for other sources to explain Solar System abundances.

Contribution

First to incorporate metallicity and progenitor mass-dependent yields of ccSNe into Galactic Chemical Evolution models for p nuclide production.

Findings

ccSNe contribute less than 10% to solar p nuclide abundances

Gamma process in ccSNe is efficient at solar metallicity but less so at lower metallicities

Other nucleosynthesis sites are likely responsible for light p-nuclides

Abstract

The production of the heavy stable proton-rich isotopes between 74Se and 196Hg -- the p nuclides -- is due to the contribution from different nucleosynthesis processes, activated in different types of stars. Whereas these processes have been subject to various studies, their relative contributions to Galactic Chemical Evolution are still a matter of debate. We investigate for the first time the nucleosynthesis of p nuclides in GCE by including metallicity and progenitor mass-dependent yields of core-collapse supernovae (ccSNe) into a chemical evolution model. We used a grid of metallicities and progenitor masses from two different sets of stellar yields and followed the contribution of ccSNe to the Galactic abundances as function of time. In combination with previous studies on p-nucleus production in thermonuclear supernovae (SNIa), and using the same GCE description, this allows us to compare the respective roles of SNeIa and ccSNe in the production of p-nuclei in the Galaxy. The gamma process in ccSN is very efficient for a wide range of progenitor masses (13M_sun_- 25M_sun) at solar metallicity. Since it is a secondary process with its efficiency depending on the initial abundance of heavy elements, its contribution is strongly reduced below solar metallicity. This makes it challenging to explain the inventory of the p nuclides in the Solar System by the contribution from ccSNe alone. In particular, we find that ccSNe contribute less than 10% of the solar p nuclide abundances, with only a few exceptions. Due to the uncertain contribution from other nucleosynthesis sites in ccSNe, such as neutrino winds or $\alpha$-rich freeze out, we conclude that the light p-nuclides 74$Se,78$Kr, 84Sr, and 92Mo may either still be completely or only partially produced in ccSNe.