# Spectral analysis of the barium central star of the planetary nebula Hen   2-39

**Authors:** L. L\"obling, H. M. J. Boffin, D. Jones

arXiv: 1902.04897 · 2019-04-03

## TL;DR

This study conducts a detailed spectral analysis of the central star of planetary nebula Hen 2-39, revealing its chemical composition, progenitor mass, and implications for mass transfer processes in binary systems with s-process element enrichment.

## Contribution

It provides the first detailed abundance analysis of the central star of Hen 2-39, constraining its progenitor mass and the mass transfer mechanism involved in its formation.

## Key findings

- Confirmed effective temperature of 4350 K.
- Detected barium overabundance of [Ba/Fe]=1.8.
- Established an upper limit for technetium abundance.

## Abstract

Barium stars are peculiar red giants characterized by an overabundance of s-process elements along with an enrichment in carbon. These stars are discovered in binaries with white dwarf companions. The more recently formed of these stars are still surrounded by a planetary nebula. Precise abundance determinations of the various s-process elements, especially, of the lightest, short-lived radionuclide technetium will establish constraints for the formation of s-process elements in asymptotic giant branch stars as well as mass transfer through, for example, stellar wind, Roche-lobe overflow, and common-envelope evolution. We performed a detailed spectral analysis of the K-type subgiant central star of the planetary nebula Hen 2-39 based on high-resolution optical spectra obtained with the Ultraviolet and Visual Echelle Spectrograph at the Very Large Telescope using LTE model atmospheres. We confirm the effective temperature of $T_\mathrm{eff} = 4350 \pm 150$ K for the central star of the planetary nebula Hen 2-39. It has a photospheric carbon enrichment of $[\mathrm{C/H}]= 0.36 \pm 0.08$ and a barium overabundance of $[\mathrm{Ba/Fe}]= 1.8 \pm 0.5$. We find a deficiency for most of the iron-group elements (calcium to iron) and establish an upper abundance limit for technetium ($\log \epsilon_\mathrm{Tc} < 2.5$). The quality of the available optical spectra is not sufficient to measure abundances of all s-process elements accurately. Despite large uncertainties on the abundances as well as on the model yields, the derived abundances are most consistent with a progenitor mass in the range 1.75-3.00 $M_\odot$ and a metallicity of $[\mathrm{Fe/H}]= -0.3 \pm 1.0$. This result leads to the conclusion that the formation of such systems requires a relatively large mass transfer that is most easily obtained via wind-Roche lobe overflow.

## Full text

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## Figures

18 figures with captions in the complete paper: https://tomesphere.com/paper/1902.04897/full.md

## References

76 references — full list in the complete paper: https://tomesphere.com/paper/1902.04897/full.md

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Source: https://tomesphere.com/paper/1902.04897