New Field OB and OBe Binaries of the SMC Wing: Observational Properties and Population Modeling

TL;DR

This study investigates the properties and population of OB and OBe star binaries in the SMC Wing through spectroscopic and photometric observations, revealing their orbital characteristics, binary fractions, and potential black hole companions.

Contribution

It provides the first detailed observational survey of OB and OBe binaries in the SMC Wing, including binary fractions, orbital properties, and population modeling with predictions for post-supernova binaries.

Findings

29% of OB stars are binaries

48% of OBe stars are binaries

Identification of 2 candidate black hole binaries

Abstract

We present a radial velocity (RV) survey of the field OB and OBe stars of the SMC Wing. We use multi-epoch observations of 55 targets obtained with the Magellan IMACS and M2FS multi-object spectrographs to identify single- and double-lined spectroscopic binaries. We also use TESS light curves to identify new eclipsing binary candidates. We find that 10 each of our 34 OB (29\%) and 21 OBe (48\%) stars are confirmed binaries, and at least $\sim$ 6 more are candidates. Using our RV measurements, we set constraints on the companion masses, and in some cases, on periods, eccentricities and inclinations. The RV data suggest that OB binaries favor more circular orbits (mean eccentricity $\langle e\rangle = 0.08\pm 0.02$) while OBe binaries are eccentric ($\langle e\rangle = 0.45\pm 0.04$). We identify 2 candidate black hole binaries, [M2002] 77616, and 81941. We use BPASS to predict the frequencies of ejected OB and OBe stars and binaries, assuming OBe stars are binary mass gainers ejected by the companion supernova. We also predict the frequencies of black-hole, neutron-star, and stripped-star companions, and we model the distributions of primary and secondary masses, periods, eccentricities, and velocity distributions. The models are broadly consistent with the binary origin scenario for OBe stars, and predict an even larger number of post-supernova OB binaries. Comparison with the kinematics supports a significant contribution from dynamical ejections for both OB and OBe stars, although less so for binaries.