Dynamical mass determination and partial eclipses of the heartbeat star HD 181793

TL;DR

This paper reports the discovery and detailed analysis of a unique eclipsing heartbeat binary star system, HD 181793, combining photometric and spectroscopic data to determine stellar masses, radii, and orbital characteristics.

Contribution

It presents the first detailed characterization of a chemically peculiar heartbeat binary, including mass determination and explanation of the heartbeat feature.

Findings

Masses of primary and secondary stars determined as 1.57 and 0.87 solar masses.

Orbital eccentricity measured at 0.3056, explaining the heartbeat feature.

No evidence of tidally-excited oscillations found.

Abstract

We identify the bright Am-type star HD 181793 to be a previously-unknown eclipsing, chemically peculiar heartbeat binary, the second of its kind known. The system carries an orbital period of $P = 11.47578275 \pm 0.00000055$ days. We use TESS photometry and LCOGT NRES radial velocity data to build a self-consistent orbital model and determine the fundamental stellar characteristics of the primary. We use a spectral separation method to unveil the secondary and measure the masses of both stars. The radial velocity amplitude of the primary, $K_1 = 47.41+0.13-0.12 km s^{-1}$, gives a mass $M_1 = 1.57 \pm 0.01 $ Msun. The secondary radial velocity amplitude $K_2 = 84.95+0.12-0.09 km s^{-1}$ yields a mass ratio $q = 0.558 \pm 0.002$ and a secondary mass $M_2 = 0.87 \pm 0.01 $ Msun. From the spectral energy distribution and Gaia parallax we find a radius $R_1 = 2.04 \pm 0.05$ Rsun. The grazing transit profile and spectroscopic luminosity ratio indicate $R_2 = 1.04+0.15-0.10$ Rsun, suggesting an early-K spectral type. We show that the heartbeat feature in the TESS light curve can be explained by time-varying ellipsoidal variation, driven by the orbital eccentricity of $e = 0.3056+0.0024-0.0026$, and relativistic beaming of the light of the primary. We find no evidence of tidally-excited oscillations.