Explaining temporal variations in the jet position angle of the blazar OJ 287 using its binary black hole central engine model

TL;DR

This paper models the jet position angle variations of blazar OJ 287 using a binary black hole central engine, linking optical and radio observations to jet precession and black hole dynamics.

Contribution

It introduces a Bayesian model connecting optical binary black hole parameters to radio jet precession, explaining observed PA variations across multiple frequencies.

Findings

The BBH model broadly explains radio jet PA variations.

Predictions for 86 GHz PA evolution can be tested with GMVA.

EHT observations could detect the secondary black hole's jet.

Abstract

The bright blazar OJ 287 is the best-known candidate for hosting a supermassive black hole binary system. It inspirals due to the emission of nanohertz gravitational waves (GWs). Observations of historical and predicted quasi-periodic high-brightness flares in its century-long optical lightcurve, allow us to determine the orbital parameters associated with the binary black hole (BBH) central engine. In contrast, the radio jet of OJ 287 has been covered with Very Long Baseline Interferometry (VLBI) observations for only about $30$ years and these observations reveal that the position angle (PA) of the jet exhibits temporal variations at both millimetre and centimetre wavelengths. Here we associate the observed PA variations in OJ 287 with the precession of its radio jet. In our model, the evolution of the jet direction can be associated either with the primary black hole (BH) spin evolution or with the precession of the angular momentum direction of the inner region of the accretion disc. Our Bayesian analysis shows that the BBH central engine model, primarily developed from optical observations, can also broadly explain the observed temporal variations in the radio jet of OJ 287 at frequencies of 86, 43, and 15 GHz. Ongoing Global mm-VLBI Array (GMVA) observations of OJ 287 have the potential to verify our predictions for the evolution of its $86$ GHz PA values. Additionally, thanks to the extremely high angular resolution that the Event Horizon Telescope (EHT) can provide, we explore the possibility to test our BBH model through the detection of the jet in the secondary black hole.