The origin of early-type runaway stars from open clusters

TL;DR

This study uses Gaia data and a new trajectory fitting method to trace the origins of early-type runaway stars, distinguishing between binary supernova and dynamical ejection mechanisms, and identifying their parent clusters.

Contribution

It introduces an efficient minimization technique for trajectory analysis, enabling precise origin identification of runaway stars from open clusters using Gaia astrometry.

Findings

Half of the studied stars are true runaways, others are walkaways, mostly binaries.

Identified parent clusters for several runaway stars, including hyper-velocity candidates.

Ejection velocities ranged from 150 to 400 km/s, indicating violent ejection events.

Abstract

Runaway stars are ejected from their place of birth in the Galactic disk, with some young B-type runaways found several tens of kiloparsecs from the plane traveling at speeds beyond the escape velocity. Young open clusters are a likely place of origin, and ejection may be either through N-body interactions or in binary supernova explosions. The excellent quality of Gaia astrometry opens up the path to study the kinematics of young runaway stars to such a high precision that the place of origin in open stellar clusters can be identified uniquely. We developed an efficient minimization method to calculate whether two or more objects may come from the same place, which we tested against samples of Orion runaways. Our fitting procedure was then used to calculate trajectories for known runaway stars where we used Gaia data and updated radial velocities. We found that only half of the sample could be classified as runaways while the others were walkaway stars. Most of the latter stars turned out to be binaries. We identified parent clusters for runaways based on their trajectories and then used cluster age and flight time of the stars to investigate whether the ejection was likely due to a binary supernova or due to a dynamical ejection. In particular, we show that the classical runaways AE Aurigae and $\mu$ Columbae might not have originated together, with $\mu$ Columbae having an earlier ejection from Collinder 69, a cluster near the ONC. The second sample investigated comprises a set of distant runaway B stars in the halo which have been studied carefully by quantitative spectral analyses. We are able to identify candidate parent clusters for at least four stars including the hyper-runaway candidate HIP 60350. The ejection events had to be very violent, ejecting stars at velocities as large as 150 to 400 km/s.