Progenitor of the recoiling super-massive black hole RBH-1 identified using HST/JWST imaging

Abstract

Using a combination of Hubble Space Telescope and James Webb Space Telescope imaging, a runaway supermassive black hole (RBH-1) was recently identified with an inferred velocity of 954+110-126\,km\,s-1, likely ejected from a compact star-forming galaxy (denoted as GX) at z ≈ 0.96. Assuming the runaway black hole was the outcome of the gravitational-wave-driven merger of two black holes, we use its measured runaway velocity together with gravitational-wave recoil predictions from numerical relativity and black hole perturbation theory to constrain the mass ratio and spin configuration of the progenitor SMBHs that overcame the final-parsec problem and merged 70~Myr ago. We find that the progenitor binary must have been precessing, with a mass ratio m1/m2 6, and that the more massive SMBH must have possessed a high spin (dimensionless spin magnitude 0.75) in order to generate a recoil of this magnitude. This has important astrophysical implications as similar SMBH mergers can be an interesting source population for the upcoming LISA mission with signal-to-noise ratios 1000. Furthermore, the progenitor SMBH properties imply that GX was likely formed through a major, gas-rich (``wet'') merger between two galaxies of comparable mass, with a mass ratio 4.