Precessional dynamics of black hole triples: binary mergers with near-zero effective spin

Abstract

The binary black hole mergers detected by Advanced LIGO/Virgo have shown no evidence of large black hole spins. However, because LIGO/Virgo best measures the effective combination of the two spins along the orbital angular momentum ( eff), it is difficult to distinguish between binaries with slowly-spinning black holes and binaries with spins lying in the orbital plane. Here, we study the spin dynamics for binaries with a distant black hole companion. For spins initially aligned with the orbital angular momentum of the binary, we find that eff "freezes" near zero as the orbit decays through the emission of gravitational waves. Through a population study, we show that this process predominantly leads to merging black hole binaries with near-zero eff. We conclude that if the detected black hole binaries were formed in triples, then this would explain their low eff without the need to invoke near-zero spins or initially large spin-orbit angles.