Orbital properties of an unusually low-mass sdB star in a close binary system with a white dwarf

TL;DR

This study analyzes a low-mass subdwarf B star in a close binary with a white dwarf using Kepler data, revealing its orbital properties, mass, and evolutionary status, and highlighting discrepancies due to observational contamination.

Contribution

It provides detailed orbital and stellar parameters of an unusually low-mass sdB star in a binary system, offering insights into its evolutionary state and mass range, which is rare and not well understood.

Findings

The sdB star shows ellipsoidal deformation and Doppler beaming effects.

The star's mass is estimated between 0.18 and 0.25 solar masses.

The system's inclination is likely around 20 degrees.

Abstract

We have used 605 days of photometric data from the Kepler spacecraft to study KIC 6614501, a close binary system with an orbital period of 0.15749747(25) days (3.779939 hours), that consists of a low-mass subdwarf B (sdB) star and a white dwarf. As seen in many other similar systems, the gravitational field of the white dwarf produces an ellipsoidal deformation of the sdB which appears in the light curve as a modulation at two times the orbital frequency. The ellipsoidal deformation of the sdB implies that the system has a maximum inclination of ~40 degrees, with i \approx 20 degrees being the most likely. The orbital radial velocity of the sdB star is high enough to produce a Doppler beaming effect with an amplitude of 432 \pm 5 ppm, clearly visible in the folded light curve. The photometric amplitude that we obtain, K1 = 85.8 km/s, is ~12 per cent less than the spectroscopic RV amplitude of 97.2 \pm 2.0 km/s. The discrepancy is due to the photometric contamination from a close object at about 5 arcsec North West of KIC 6614501, which is difficult to remove. The atmospheric parameters of the sdB star, Teff = 23 700 \pm 500 K and log g = 5.70 \pm 0.10, imply that it is a rare object below the Extreme Horizontal Branch (EHB), similar to HD 188112 (Heber et al. 2003). The comparison with different evolutionary tracks suggests a mass between ~0.18 and ~0.25 Msun, too low to sustain core helium burning. If the mass was close to 0.18-0.19 Msun, the star could be already on the final He-core WD cooling track. A higher mass, up to ~0.25 Msun, would be compatible with a He-core WD progenitor undergoing a cooling phase in a H-shell flash loop. A third possibility, with a mass between ~0.32 and ~0.40 Msun, can not be excluded and would imply that the sdB is a "normal" (but with an unusually low mass) EHB star burning He...