# Possible pair-instability supernovae at solar metallicity from magnetic   stellar progenitors

**Authors:** Cyril Georgy, Georges Meynet, Sylvia Ekstr\"om, Gregg A. Wade,, V\'eronique Petit, Zsolt Keszthelyi, Raphael Hirschi

arXiv: 1702.02340 · 2017-03-01

## TL;DR

This study demonstrates that magnetic fields in very massive stars at solar metallicity can significantly reduce mass loss, enabling such stars to reach conditions necessary for pair-instability supernovae, which was previously thought unlikely.

## Contribution

It introduces magnetic field effects into stellar evolution models, showing that magnetic braking and reduced mass loss can lead to PISNe at solar metallicity, a novel insight.

## Key findings

- Magnetic fields reduce stellar mass loss at solar metallicity.
- Magnetic models can produce CO cores suitable for PISNe.
- Rotational mixing leads to nearly homogeneous evolution.

## Abstract

Near-solar metallicity (and low-redshift) Pair-Instability Supernova (PISN) candidates challenge stellar evolution models. Indeed, at such a metallicity, even an initially very massive star generally loses so much mass by stellar winds that it will avoid the electron-positron pair-creation instability. We use recent results showing that a magnetic field at the surface of a massive star can significantly reduce its effective mass-loss rate to compute magnetic models of very massive stars (VMSs) at solar metallicity and explore the possibility that such stars end as PISNe. We implement the quenching of the mass loss produced by a surface dipolar magnetic field into the Geneva stellar evolution code and compute new stellar models with an initial mass of $200\,M_\odot$ at solar metallicity, with and without rotation. It considerably reduces the total amount of mass lost by the star during its life. For the non-rotating model, the total (CO-core) mass of the models is $72.8\,M_\odot$ ($70.1\,M_\odot$) at the onset of the electron-positron pair-creation instability. For the rotating model, we obtain $65.6\,M_\odot$ ($62.4\,M\odot$). In both cases, a significant fraction of the internal mass lies in the region where pair instability occurs in the $\log(T)-\log(\rho)$ plane. The interaction of the reduced mass loss with the magnetic field efficiently brakes the surface of the rotating model, producing a strong shear and hence a very efficient mixing that makes the star evolve nearly homogeneously. The core characteristics of our models indicate that solar metallicity models of magnetic VMSs may evolve to PISNe (and pulsation PISNe).

## Full text

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## Figures

8 figures with captions in the complete paper: https://tomesphere.com/paper/1702.02340/full.md

## References

29 references — full list in the complete paper: https://tomesphere.com/paper/1702.02340/full.md

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Source: https://tomesphere.com/paper/1702.02340