The origin of the most recently ejected OB runaway star from the R136 cluster

Abstract

The 60\,000 solar-mass () star-cluster R136 (NGC~2070) in the Tarantula Nebula in the Large Magellanic Cloud is the host of at least 55 massive stars (M 10\,) which move away from the cluster at projected velocities 27.5\,km/s 2024Natur.634..809S. The origin of the high velocities of such runaway stars have been debated since the 1960s, resulting either from dynamical ejections 1961BAN....15..265B,1961BAN....15..291B or from supernova explosions 1983ApJ...267..322H. Due to the Gaia satellite's outstanding precision, we can now retrace the most recently ejected binary star, Mel 34, back to the center of R136 and reconstruct the events that 52\,000 years ago let to its removal from R136, i.e., we establish its dynamical interaction and ejection history. We find that this ejection requires the participation of 5 stars in a strong interaction between a triple composed of the tight massive binary Mel~39 orbited by the star VFTS~590, and the binary star Mel~34. The participation of 5 stars is unexpected because runaway stars were not expected to result from triple interactions 2011Sci...334.1380F. The deterministic nature of the Newtonian dynamics in the scattering enables us to reconstruct the encounter that ejected Mel~34. We then predict that Mel~39 is a binary star with an 80\,\, companion star that orbits within 1 in the same plane as Mel~34, and escapes the cluster with a velocity of 64\,km/s. The five stars will undergo supernova explosions in the coming 5\,Myr at a distance of 180\,pc to 332\,pc from their birth location (R\,136). The resulting black hole binaries, however, are not expected to merge within a Hubble time.