Photometric Analysis of the OGLE Heartbeat Stars

TL;DR

This study analyzes 991 heartbeat stars from the OGLE survey, modeling their light curves to understand their orbital and evolutionary properties, and detects tidally-excited oscillations in a subset of these systems.

Contribution

It provides the first large homogeneous analysis of heartbeat stars, including their distribution, evolutionary status, and tidally-excited oscillations, revealing new correlations between orbital harmonics and eccentricity.

Findings

Two distinct groups of heartbeat stars identified by evolutionary status.

Detection of tidally-excited oscillations in about 5% of the sample.

Correlation between orbital harmonic number and eccentricity.

Abstract

We present an analysis of 991 heartbeat stars (HBSs) from the OGLE Collection of Variable Stars (OCVS). The sample consists of 512 objects located toward the Galactic bulge (GB), 439 in the Large Magellanic Cloud (LMC) and 40 in the Small Magellanic Cloud (SMC). We model the $I$-band OGLE light curves using an analytical model of flux variations, reflecting tidal deformations between stars. We present distributions of the model parameters that include the eccentricity, orbital inclination, and argument of the periastron, but also the period-amplitude diagrams. On the Hertzsprung-Russell (HR) diagram, our HBS sample forms two separate groups of different evolutionary status. The first group of about 90 systems, with short orbital periods ($P\lesssim50$~days), consists of an early-type primary star lying on (or close to) the main sequence (MS). The second group of about 900 systems, with long orbital periods ($P\gtrsim100$~days), contains a red giant (RG). The position of RG HBSs on the period-luminosity diagram strongly indicates their binary nature. They appear to be a natural extension of confirmed binary systems that include the OGLE ellipsoidal and Long Secondary Period (LSP) variables. We also present a time-series analysis leading to detection of tidally-excited oscillations (TEOs). We identify such pulsations in about 5\% of stars in the sample with a total number of 78 different modes. This first relatively large homogeneous sample of TEOs allowed us to construct a diagram revealing the correlation between the TEO's orbital harmonic number and the eccentricity of the host binary system.