Signatures of spin precession and nutation in isolated black-hole binaries

Abstract: The spin precession of binary black holes (BBHs) that originate from isolated high-mass binary stars is determined by the interplay of phenomena such as tides, winds, accretion, common-envelope evolution, natal kicks, and stellar core-envelope coupling. In previous work, we identified regions of the parameter space that may produce BBHs with large misalignments from natal kicks and high spin magnitudes from three mechanisms -tides, accretion, or inheritance via minimal core-envelope coupling. Here, we explore … Show more

“…In particular, morphology measurement in GWs enables us to constrain certain formation channels or different evolutionary scenarios of stellar progenitors of field BBHs in some cases, e.g., when tidal alignment and natal kicks are significant [37,38]. See also [39] for more recent work relating the morphologies in the ground-based detector band with astrophysical processes in the binaries' formation.…”

Distinguishing binary black hole precessional morphologies with gravitational wave observations

“…In particular, morphology measurement in GWs enables us to constrain certain formation channels or different evolutionary scenarios of stellar progenitors of field BBHs in some cases, e.g., when tidal alignment and natal kicks are significant [37,38]. See also [39] for more recent work relating the morphologies in the ground-based detector band with astrophysical processes in the binaries' formation.…”

Distinguishing binary black hole precessional morphologies with gravitational wave observations

Precessing binary black holes as better dark sirens

Efficient multi-timescale dynamics of precessing black-hole binaries