The abundances and properties of Dual AGN and their host galaxies in the EAGLE simulations

TL;DR

This study uses the EAGLE simulations to analyze the abundance, properties, and detectability of Dual AGN systems, revealing low occurrence rates and the impact of galaxy mergers on their visibility.

Contribution

It provides the first detailed simulation-based analysis of Dual AGN abundance, properties, and detection probabilities across cosmic time.

Findings

Only 1% of AGN are Dual systems at z=0.8-1.

The average detection probability of Dual AGN is 3%.

The distribution peaks at ~20 kpc separation.

Abstract

We look into the abundance of Dual AGN in the largest hydrodynamical simulation from the EAGLE project. We define a Dual AGN as two active black holes (BHs) with a separation below 30 kpc. We find that only 1 per cent of AGN with $\LhX\geq 10^{42}\ergs$ are part of a Dual AGN system at $z=0.8-1$. During the evolution of a typical binary BH system, the rapid variability of the hard X-ray luminosity on Myr time-scales severely limits the detectability of Dual AGN. To quantify this effect, we calculate a probability of detection, $t_{\rm on}/t_{\rm 30}$, where $t_{\rm 30}$ is the time in which the two black holes are separated at distances below 30 kpc and $t_{\rm on}$, the time that both AGN are visible (e.g. when both AGN have $\LhX\geq 10^{42}\ergs$) in this period. We find that the average fraction of visible Dual systems is 3 per cent. The visible Dual AGN distribution as a function of BH separation presents a pronounced peak at $\sim 20$ kpc that can be understood as a result of the rapid orbital decay of the host galaxies after their first encounter. We also find that $75$ per cent of the host galaxies have recently undergone or are undergoing a merger with stellar mass ratio $\geq 0.1$. Finally, we find that the fraction of visible Dual AGN increases with redshift as found in observations.