Detection and characterization of spin-orbit resonances in the advanced gravitational wave detectors era

Abstract

In this paper, we test the performance of templates in detection and characterization of Spin-orbit resonant (SOR) binaries. We use precessing SEOBNRv3 waveforms as well as four numerical relativity (NR) waveforms to model GWs from SOR binaries and filter them through IMRPhenomD, SEOBNRv4 (non-precessing) and IMRPhenomPv2 (precessing) approximants. We find that IMRPhenomD and SEOBNRv4 recover only 70\% of injections with fitting factor (FF) higher than 0.97 (or 90\% of injections with FF >0.9).However, using the sky-maxed statistic, IMRPhenomPv2 performs magnificently better than their non-precessing counterparts with recovering 99\% of the injections with FFs higher than 0.97. Interestingly, injections with φ = 180 have higher FFs ( φ is the angle between the components of the black hole spins in the plane orthogonal to the orbital angular momentum) as compared to their φ =0 and generic counterparts. This implies that we will have a slight observation bias towards φ=180 SORs while using non-precessing templates for searches. All template approximants are able to recover most of the injected NR waveforms with FFs >0.95. For all the injections including NR, the error in estimating chirp mass remains below <10\% with minimum error for φ = 180 resonant binaries. The symmetric mass ratio can be estimated with errors below 15\%. The effective spin parameter eff is measured with maximum absolute error of 0.13. The in-plane spin parameter p is mostly underestimated indicating that a precessing signal will be recovered as a relatively less precessing signal. Based on our findings, we conclude that we not only need improvements in waveform models towards precession and non-quadrupole modes but also better search strategies for precessing GW signals.