# Accretion-Induced Collapse From Helium Star + White Dwarf Binaries

**Authors:** Jared Brooks, Josiah Schwab, Lars Bildsten, Eliot Quataert, Bill, Paxton

arXiv: 1706.03843 · 2017-08-02

## TL;DR

This study uses stellar simulations to explore how helium star and white dwarf binaries can lead to accretion-induced collapse, providing new insights into the conditions and processes that trigger this astrophysical event.

## Contribution

First binary simulations of helium star + O/Ne white dwarf systems demonstrating the pathway to accretion-induced collapse with detailed stellar processes.

## Key findings

- Stable helium burning on the white dwarf surface.
- Inwardly moving carbon burning flame initiates collapse.
- Potential dominant channel for AIC in binary populations.

## Abstract

Accretion-induced collapse (AIC) occurs when an O/Ne white dwarf (WD) grows to nearly the Chandrasekhar mass ($M_{\rm Ch}$), reaching central densities that trigger electron captures in the core. Using Modules for Experiments in Stellar Astrophysics ($\texttt{MESA}$), we present the first true binary simulations of He star + O/Ne WD binaries, focusing on a $1.5 M_\odot$ He star in a 3 hour orbital period with $1.1-1.3 M_\odot$ O/Ne WDs. The helium star fills its Roche lobe after core helium burning is completed and donates helium on its thermal timescale to the WD, $\dot{M}\approx3\times10^{-6} M_\odot$/yr, a rate high enough that the accreting helium burns stably on the WD. The accumulated carbon/oxygen ashes from the helium burning undergo an unstable shell flash that initiates an inwardly moving carbon burning flame. This flame is only quenched when it runs out of carbon at the surface of the original O/Ne core. Subsequent accumulation of fresh carbon/oxygen layers also undergo thermal instabilities, but no mass loss is triggered, allowing $M_{\rm WD}\rightarrow M_{\rm Ch}$, triggering the onset of AIC. We also discuss the scenario of accreting C/O WDs that experience shell carbon ignitions to become O/Ne WDs, and then, under continuing mass transfer, lead to AIC. Studies of the AIC event rate using binary population synthesis should include all of these channels, especially this latter channel, which has been previously neglected but might dominate the rate.

## Full text

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## Figures

8 figures with captions in the complete paper: https://tomesphere.com/paper/1706.03843/full.md

## References

43 references — full list in the complete paper: https://tomesphere.com/paper/1706.03843/full.md

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Source: https://tomesphere.com/paper/1706.03843