The role of Massive Black Holes in merging star clusters: dynamical evolution, stellar & compact object ejections and gravitational waves
Abstract
Star clusters can interact and merge in galactic discs, halos, or centers. We present direct N-body simulations of binary mergers of star clusters with M = 2.7 × 104 \: M each, using the N-body code BIFROST with subsystem regularisation and post-Newtonian dynamics. We include 500 M massive black holes (MBHs) in the progenitors to investigate their impact on remnant evolution. The MBHs form hard binaries interacting with stars and stellar black holes (BHs). A few Myr after the cluster merger, this produces sizable populations of runaway stars (800 with vej 50 kms-1) and stellar BHs (30) escaping within 100 Myr. The remnants lose 30\% of their BH population and 3\% of their stars, with 30 stars accelerated to high velocities 300 kms-1. Comparison simulations of isolated clusters with central hard MBH binaries and cluster mergers without MBHs show that the process is driven by MBH binaries, while those with a single 1000 M MBH in isolated or merging clusters produce fewer runaway stars at lower velocities. Low-eccentricity merger orbits yield rotating remnants (vrot 3 kms-1) , but probing the presence of MBHs via kinematics alone remains challenging. We expect the binary MBHs to merge within a Hubble time, producing observable gravitational-wave (GW) events detectable by future GW detectors such as the Einstein Telescope and LISA. The results suggest that interactions with low-mass MBH binaries formed in merging star clusters are an important additional channel for producing runaway and high-velocity stars, free-floating stellar BHs and compact objects.
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