VLTI/GRAVITY enables the determination of the first dynamical masses of a classical Be + stripped and bloated pre-subdwarf binary

TL;DR

This study uses VLTI/GRAVITY interferometry to determine the first dynamical masses of a classical Be star and a bloated pre-subdwarf binary, providing key insights into their evolutionary stages.

Contribution

It presents the first direct dynamical mass measurements of a Be + pre-subdwarf binary using interferometry combined with spectroscopy, revealing detailed orbital and stellar parameters.

Findings

Be star is nearly 16 times more massive than the stripped star.

The orbit has a slight eccentricity of about 0.029.

Dynamical masses are 4.24 and 0.27 solar masses for the Be and stripped stars.

Abstract

HR~6819 is the first post-mass transfer binary system composed of a classical Be star and a bloated pre-subdwarf stripped star directly confirmed by interferometry. While the Be star is already spun up to near-critical rotation and possesses a self-ejected viscous Keplerian disk, the stripped star is found in a short-lived evolutionary stage, in which it retains the spectral appearance of a B-type main-sequence star while contracting into a faint subdwarf OB-type star. In order to understand the evolution of intermediate-mass interacting binaries, the fundamental parameters of cornerstone objects such as HR~6819 need to be known. We aim to obtain orbital parameters and model-independent dynamical masses of this binary system to quantitatively characterize this rarely observed evolutionary stage. We analyzed a time series of 12 interferometric near-IR $K$-band observations from VLTI/GRAVITY with the help of the geometrical model-fitting tool PMOIRED. We included recently published radial velocities based on FEROS high-resolution spectroscopy for the binary orbital solution. With the GRAVITY data, we obtained the astrometric orbit, relative fluxes of the components, and parameters of the circumstellar disk of the Be star; we also detected helium line signatures from the stripped star. Using the published radial velocities enabled us to obtain the dynamical masses of the components as well as the dynamical parallax. The Be star is the slightly brighter component in the $K$ band and is almost 16 times as massive as the bloated stripped star, with the individual dynamical masses being $4.24\pm0.31 {\rm M}_{\odot}$ for the Be star and $0.270\pm0.056 {\rm M}_{\odot}$ for the stripped star. The orbit is slightly eccentric, with $e=0.0289\pm0.0058$, and the semimajor axis of the orbit is $0.3800\pm0.0093$ AU. (Abstract continues but does not fit here)