Accretion, Jets, and Recoil in Merging Supermassive Binary Black Holes

We report the first 3D general relativistic magnetohydrodynamic (GRMHD) simulation that captures the full, self-consistent evolution from the late inspiral through merger and subsequent recoil of a supermassive binary black hole (SMBBH) with misaligned spins embedded in an equilibrated circumbinary disk (CBD). Our full numerical simulation follows the final 40 orbits of the inspiral and merger of the binary, following an initial phase of 165 orbits of CBD evolution toward equilibrium. We find that the jets, launched from the minidisks surrounding each black hole, are tilted toward the black hole spin direction close to the individual black holes, but align with the binary's total angular momentum at larger distances. Following the merger, the remnant black hole receives a recoil kick exceeding 1000 km/s. Remarkably, it retains its gravitationally bound CBD as if it were ejected from a galactic nucleus. Furthermore, the jet launched by the recoiling remnant black hole preserves the large-scale orientation established during the late inspiral. We demonstrate that the majority of the luminosity emerges from a region in close proximity to the black hole, suggesting that the accretion disk surrounding the recoiling remnant would remain the most luminous feature postmerger, persisting for long enough to be observable by modern telescopes (hours in the case of LISA sources). These findings introduce a direct, first-principles model for the recoil of supermassive black holes (SMBH) in active galactic nuclei (AGNs), offering a comprehensive theoretical basis to support and elucidate both ongoing and future observational efforts.