Caught in the act: detections of recoiling supermassive black holes from simulations

Abstract

We study the detectability of supermassive black holes (SMBHs) with masses of M 109\,M displaced by gravitational wave recoil kicks (v kick=0-2000\,km\,s-1) in simulations of merging massive (M>1011\,M) early-type galaxies. The used KETJU code combines the GADGET-4 fast multiple gravity solver with accurate regularised integration and post-Newtonian corrections (up to PN3.5) around SMBHs. The ejected SMBHs carry clusters of bound stellar material (black hole recoil clusters, BRCs) with masses in the range of 106 MBRC 107\,M and sizes of several 10\,pc. For recoil velocities up to 60\% of the galaxy escape velocity, the BRCs are detectable in mock photometric images at a Euclid-like resolution up to redshift z 1.0. By Monte Carlo sampling the observability for different recoil directions and magnitudes, we predict that in 20\% of instances the BRCs are photometrically detectable, most likely for kicks with SMBH apocentres less than the galaxy effective radius. BRCs occupy distinct regions in the stellar mass/velocity dispersion vs. size relations of known star clusters and galaxies. An enhanced velocity dispersion in excess of σ 600\,km\,s-1 coinciding with the SMBH position provides the best evidence for an SMBH-hosting stellar system, effectively distinguishing BRCs from other faint stellar systems. BRCs are promising candidates to observe the aftermath of the yet-undetected mergers of the most massive SMBHs and we estimate that up to 8000 BRCs might be observable below z 0.6 with large-scale photometric surveys such as Euclid and upcoming high-resolution imaging and spectroscopy with the Extremely Large Telescope.