Standard Siren Cosmology with Gravitational Waves from Binary Black Hole Mergers in Active Galaxy Nuclei

Abstract

The detection of gravitational waves (GW) with an electromagnetic counterpart enabled the first Hubble Constant H0 measurement through the standard siren method. Current constraints suggest that 20-30\% of LIGO/Virgo/KAGRA (LVK) Binary Black Hole (BBH) mergers might occur in Active Galactic Nuclei (AGN) disks. The claim for a possible association of several BBH mergers with flaring AGNs suggests that cosmological analyses using BBH and AGNs might be promising. We explore standard siren analyses through a method that takes into account the presence of background flaring AGNs, without requiring a unique host galaxy identification, and apply it to realistic GW simulations. Depending on the fraction of LVK BBHs that induce flares, we expect to constrain H0 at the 6-7\% ( 4-5\%) precision with 2-3 years or 160-240 events ( 1 year or 500 events) of LVK at design (A+) sensitivity, assuming that systematic BBH follow-up searches are performed. %Assuming a more restrictive m prior and that at least 20\% of BBHs produces detectable flares, we may reach a 3\% (2\%) precision in H0 after 2 (1) year of LVK at design (A+) sensitivity. We also show that in a scenario where only 1\% of the BBHs induce detectable flares it is possible to achieve an H0 precision from 7.5\% to 15\% with 240 events. In addition, a 5-27\% precision is achievable with complete AGN catalogs and 1 year of LVK run, without the need of any flare identification.