Spectral analysis of four surprisingly similar hot hydrogen-rich subdwarf O stars

TL;DR

This study conducts a detailed spectroscopic analysis of four bright hot hydrogen-rich subdwarf O stars, revealing their similar atmospheric parameters, chemical abundances, and potential binary nature, using non-LTE models and multi-wavelength spectra.

Contribution

It provides the first comprehensive comparison of four bright sdO stars, highlighting their similar properties and potential binary status, with detailed abundance and rotational velocity measurements.

Findings

Stars have Teff between 60,000 and 63,000 K and log g 5.9-6.1.

UV spectra show strong iron and nickel lines with significant enrichment.

Feige 34 has an infrared excess consistent with a binary companion.

Abstract

We perform a comprehensive spectroscopic analysis of four such bright sdO stars, namely Feige 34, Feige 67, AGK$+$81 266, and LS II$+$18 9, among which the first three are used as standard stars for flux calibration. We used non-local thermodynamic equilibrium model atmospheres in combination with high quality optical and UV spectra. Photometric data were also used to compute the spectroscopic distances of our stars and to characterize the companion responsible for the infrared excess of Feige 34. The four bright sdO stars have very similar atmospheric parameters with Teff between 60 000 and 63 000 K and log g in the range 5.9 to 6.1. This places these objects right on the theoretical post-EHB evolutionary tracks. The UV spectra are dominated by strong iron and nickel lines and suggest abundances that are enriched with respect to those of the Sun by factors of 25 and 60. On the other hand, the lighter elements, C, N, O, Mg, Si, P, and S, are depleted. The stars have very similar abundances, although AGK$+$81 266 shows differences in its light element abundances. For instance, the helium abundance of this object is 10 times lower than that observed in the other three stars. All our stars show UV spectral lines that require additional line broadening that is consistent with a rotational velocity of about 25 km s$^{-1}$. The infrared excess of Feige 34 is well reproduced by a M0 main-sequence companion and the surface area ratio of the two stars suggests that the system is a physical binary. However, the lack of radial velocity variations points towards a low inclination and/or long orbital period. Spectroscopic and Hipparcos distances are in good agreement for our three brightest stars.