Ordering the chaos: stellar black hole mergers from non-hierarchical triples
Authors:
Manuel Arca-Sedda, Gongjie Li, Bence Kocsis
Abstract:
We investigate the evolution of triple, non-hierarchical, black hole (BH)
systems making use of $2.9\times10^4$ 3-body simulations. Varying the mutual
orbital inclination, the three BH masses and the inner and outer
eccentricities, we show that retrograde, nearly planar configurations lead to a
significant shrinkage of the inner binary. We find an universal trend of triple
systems, that they tend to evolve toward prograde configurations, Moreover, we
demonstrate that the orbital flip, driven by the torque exerted on the inner BH
binary (BHB) by the outer BH, leads in general to tighter inner orbits. In some
cases, the resulting BHB undergoes coalescence within a Hubble time, releasing
gravitational waves (GWs). Frequently, the inner BHB merger occurs after a
component swap between one of its components and the outer BH. The mass
spectrum of the BHBs that underwent the component exchange differs
significantly from the case in which the BHB merge without any swap. A large
fraction of merging BHBs with initial separation $1$ AU enter the
$10^{-3}-10^{-1}$ Hz frequency band with large eccentricities, thus
representing potential LISA sources. Mergers originating from initially tighter
BHB ($a\sim 0.01$ AU), instead, have a large probability to have eccentricities
above 0.7 in the $1$ Hz band. We find that the mergers' mass distribution in
this astrophysical channel maps the original BH binary spectrum. This might
have interesting consequences in light of the growing population of BH mergers
detected by LIGO.
