The mass range of hot subdwarf B stars from MESA simulations

Abstract

ABSTRACT Hot subdwarf B (sdB) stars are helium core burning stars that have lost almost their entire hydrogen envelope due to binary interaction. Their assumed canonical mass of ${M_{\mathrm{sdB}}}\sim 0.47$ M⊙ has recently been debated given a broad range found both from observations as well as from the simulations. Here, we revise and refine the mass range for sdBs derived two decades ago with the Eggleton code, using the stellar evolution code mesa, and discuss the effects of metallicity and the inclusion of core overshooting during the main sequence. We find an excellent agreement for low-mass progenitors, up to ∼2.0 M⊙. For stars more massive than ∼2.5 M⊙, we obtain a wider range of sdB masses compared to the simulations from the literature. Our mesa models for the lower metallicity predict, on average, slightly more massive sdBs. Finally, we show the results for the sdB lifetime as a function of sdB mass and discuss the effect this might have in the comparison between simulations and observational samples. This study paves the way for reproducing the observed Galactic mass distribution of sdB binaries.