Black Hole and Neutron Star Binary Mergers in Triple Systems: II. Merger Eccentricity and Spin-Orbit Misalignment

Abstract

We study the dynamical signatures of black hole (BH) and neutron star (NS) binary mergers via Lidov-Kozai oscillations induced by tertiary companions in hierarchical triple systems. For each type of binaries (BH-BH and BH-NS), we explore a wide range of binary/triple parameters that lead to binary mergers, and determine the distributions of eccentricity (em) and spin-orbit misalignment angle (θ sl f) when the binary enters the LIGO/VIRGO band. We use the double-averaged (over both orbits) and single-averaged (over the inner orbit) secular equations, as well as N-body integration, to evolve systems with different hierarchy levels, including the leading-order post-Newtonian effect, spin-orbit coupling and gravitational radiation. We find that for merging BH-BH binaries with comparable masses, about 7\% have em>0.1 and 0.7\% have e m>0.9. The majority of the mergers have significant eccentricities in the LISA band. The BH spin evolution and θ sl f are correlated with the orbital evolution and e m. Mergers with e m 10-3 have a distribution of θ sl f that peaks around 90 (and thus favoring a projected binary spin parameter eff 0), while mergers with larger e m have a more isotropic spin-orbit misalignments. For typical BH-NS binaries, strong octuple effects lead to more mergers with non-negligible em (with 18\% having em>0.1 and 2.5\% having em>0.9), and the final BH spin axis tends to be randomly orientated. Measurements or constraints on eccentric mergers and θ sl f from LIGO/VIRGO and LISA would provide useful diagnostics on the dynamical formation of merging BH or NS binaries in triples.