# Chromium Nucleosynthesis and Silicon-Carbon Shell Mergers in Massive   Stars

**Authors:** Benoit C\^ot\'e, Samuel Jones, Falk Herwig, Marco Pignatari

arXiv: 1906.07218 · 2020-04-08

## TL;DR

This study investigates how silicon-carbon shell mergers in massive stars influence chromium production and galactic chemical evolution, revealing that such mergers can significantly alter element yields and challenge existing models.

## Contribution

It demonstrates that silicon-carbon shell mergers in 20 solar mass stars at specific metallicities can cause large chromium overproduction, impacting galactic chemical evolution models.

## Key findings

- Shell mergers lead to increased Cr-rich material ejection.
- Current models overestimate [Cr/Fe] when including these mergers.
- Shell mergers may induce convective-reactive oscillations.

## Abstract

We analyze the production of the element Cr in galactic chemical evolution (GCE) models using the NuGrid nucleosynthesis yields set. We show that the unusually large [Cr/Fe] abundance at [Fe/H] $\approx 0$ reported by previous studies using those yields and predicted by our Milky Way model originates from the merging of convective Si-burning and C-burning shells in a 20 $M_\odot$ model at metallicity $Z=0.01$, about an hour before the star explodes. This merger mixes the incomplete burning material in the Si shell, including $^{51}$V and $^{52}$Cr, out to the edge of the carbon/oxygen (CO) core. The adopted supernova model ejects the outer 2 $M_\odot$ of the CO core, which includes a significant fraction of the Cr-rich material. When including this 20 $M_\odot$ model at $Z=0.01$ in the yields interpolation scheme of our GCE model for stars in between 15 and 25 $M_\odot$, we overestimate [Cr/Fe] by an order of magnitude at [Fe/H] $\approx$ 0 relative to observations in the Galactic disk. This raises a number of questions regarding the occurrence of Si-C shell mergers in nature, the accuracy of different simulation approaches, and the impact of such mergers on the pre-supernova structure and explosion dynamics. According to the conditions in this 1D stellar model, the substantial penetration of C-shell material into the Si-shell could launch a convective-reactive global oscillation, if a merger does take place. In any case, GCE provides stringent constraints on the outcome of this stellar evolution phase.

## Full text

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## Figures

7 figures with captions in the complete paper: https://tomesphere.com/paper/1906.07218/full.md

## References

50 references — full list in the complete paper: https://tomesphere.com/paper/1906.07218/full.md

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Source: https://tomesphere.com/paper/1906.07218