The effect of 12C + 12C rate uncertainties on the evolution and nucleosynthesis of massive stars

TL;DR

This study investigates how uncertainties in the 12C + 12C fusion reaction rate affect the evolution and nucleosynthesis of massive stars, revealing significant impacts on core burning, convection, and element production.

Contribution

The paper presents new stellar models exploring different 12C + 12C reaction rates and their effects on star structure and nucleosynthesis, including s-process element yields.

Findings

Enhanced reaction rate leads to earlier core carbon ignition at lower temperatures.

Increased rate extends the mass range for convective carbon cores.

Yields show significant production of elements like Kr, Sr, Y, Zr, Mo, Ru, Pd, and Cd.

Abstract

[Shortened] The 12C + 12C fusion reaction has been the subject of considerable experimental efforts to constrain uncertainties at temperatures relevant for stellar nucleosynthesis. In order to investigate the effect of an enhanced carbon burning rate on massive star structure and nucleosynthesis, new stellar evolution models and their yields are presented exploring the impact of three different 12C + 12C reaction rates. Non-rotating stellar models were generated using the Geneva Stellar Evolution Code and were later post-processed with the NuGrid Multi-zone Post-Processing Network tool. The enhanced rate causes core carbon burning to be ignited more promptly and at lower temperature. This reduces the neutrino losses, which increases the core carbon burning lifetime. An increased carbon burning rate also increases the upper initial mass limit for which a star exhibits a convective carbon core. Carbon shell burning is also affected, with fewer convective-shell episodes and convection zones that tend to be larger in mass. Consequently, the chance of an overlap between the ashes of carbon core burning and the following carbon shell convection zones is increased, which can cause a portion of the ashes of carbon core burning to be included in the carbon shell. Therefore, during the supernova explosion, the ejecta will be enriched by s-process nuclides synthesized from the carbon core s process. The yields were used to estimate the weak s-process component in order to compare with the solar system abundance distribution. The enhanced rate models were found to produce a significant proportion of Kr, Sr, Y, Zr, Mo, Ru, Pd and Cd in the weak component, which is primarily the signature of the carbon-core s process. Consequently, it is shown that the production of isotopes in the Kr-Sr region can be used to constrain the 12C + 12C rate using the current branching ratio for a- and p-exit channels.