Long Term (250 years) Hydrodynamical Simulation of the Supermassive Black Hole Binary OJ287

Abstract

With upcoming facilities capable of detecting photometric and gravitational wave signals from supermassive black hole (SMBH) binaries, studying their long-term accretion-driven variability is timely. OJ287 is a bright, nearby (z=0.3), and well-studied candidate for a SMBH binary. As such, it is an excellent case study for how binary dynamics could influence observed active galactic nucleus (AGN) photometric variability. We present 3D hydrodynamic simulations of OJ287, using the code PHANTOM. We simulate two mass ratios: (i) M1 = 1.835×1010 M with M2 = 1.4×108 M, (ii) M1≈ M2 (108 M) along and (iii) control of a single SMBH and accretion disc. We find that the simulation with masses 1.835×1010 M and 1.4×108 M evolves consistently with the most currently accepted model of OJ287 as a precessing SMBH binary. The secondary's impacts with the disc result in the formation of spiral density waves and a corresponding 10-20% increases in the mass accretion rate of the primary SMBH. The impact timings and the mass accretion rate spikes show quasi-periodic variability as a result of the precession of the secondary's orbit with intervals between impacts ranging from 1 year to 10 years. In the near-equal mass case, the disc of the primary becomes tidally disrupted after 2 years. Consequently, the near-equal mass system with a period of 12 years is not a viable candidate for OJ287. This modeling provides insights into the potential signatures of SMBH binaries by both gravitational wave observatories and the Rubin Legacy Survey of Space and Time.