Spectral models for binary products: Unifying Subdwarfs and Wolf-Rayet stars as a sequence of stripped-envelope stars

TL;DR

This paper presents the first spectral models for binary-stripped stars, revealing a continuous sequence bridging subdwarfs and Wolf-Rayet stars, with implications for understanding ionizing radiation and stellar evolution.

Contribution

The study provides a comprehensive grid of spectral models for stripped stars across various masses and metallicities, unifying different stellar types and challenging previous assumptions about their properties.

Findings

Stripped stars exhibit high temperatures and luminosities similar to progenitors.

Spectra form a continuous sequence from subdwarfs to Wolf-Rayet stars.

Detection strategies include UV excess and emission lines like HeII4686 and HeII1640.

Abstract

Stars stripped of their envelope through interaction in a binary are generally not considered when accounting for ionizing radiation from stellar populations, despite the expectation that stripped stars emit hard ionizing radiation, form frequently and live 10-100 times longer than single massive stars. We compute the first grid of spectral models specially made for stars stripped in binaries for a range of progenitor masses (2-20$M_{\odot}$) and metallicities covering a wide range. For stripped stars with masses between 0.3-7$M_{\odot}$, we find high effective temperatures (20-100 kK, increasing with mass), small radii (0.2-1$R_{\odot}$) and high bolometric luminosities, comparable to that of their progenitor before stripping. The spectra show a continuous sequence that naturally bridges subdwarf-type stars and Wolf-Rayet like spectra. For intermediate masses we find hybrid spectral classes showing a mixture of absorption and emission lines. These appear for stars with mass loss rates of $10^{-8}-10^{-6}M_{\odot}$/yr, which have semi-transparent atmospheres. At low metallicity, substantial H-rich layers are left at the surface and we predict spectra that resemble O-type stars instead. We obtain spectra undistinguishable from subdwarfs for stripped stars with masses up to 1.7$M_{\odot}$, which questions whether the widely adopted canonical value of 0.47$M_{\odot}$ is uniformly valid. Increasing the observed sample of stripped stars will provide necessary tests for the physics of interaction, internal mixing and stellar winds. We investigate the feasibility to detect stripped stars next to an optically bright companion and recommend searches for their UV excess and possible emission lines, most notably HeII4686 in the optical and HeII1640 in the UV. Our models are publicly available for further investigations or inclusion in spectral synthesis simulations.