Effective-one-body waveforms for precessing coalescing compact binaries with post-newtonian Twist

Abstract

Spin precession is a generic feature of compact binary coalescences, which leaves clear imprints in the gravitational waveforms. Building on previous work, we present an efficient time domain inspiral-merger-ringdown effective-one-body model (EOB) for precessing binary black holes, which incorporates subdominant modes beyond =2, and the first EOB frequency domain approximant for precessing binary neutron stars. We validate our model against 99 ``short'' numerical relativity precessing waveforms, where we find median mismatches of 5× 10-3, 7 × 10-3 at inclinations of 0, π/3, and 21 ``long'' waveforms with median mismatches of 4 × 10-3 and 5 × 10-3 at the same inclinations. Further comparisons against the state-of-the-art NRSur7dq4 waveform model yield median mismatches of 4× 10-3, 1.8 × 10-2 at inclinations of 0, π/3 for 5000 precessing configurations with the precession parameter p up to 0.8 and mass ratios up to 4. To demonstrate the computational efficiency of our model we apply it to parameter estimation and re-analyze the gravitational-wave events GW150914, GW190412, and GW170817.