New gravitational waveform model for precessing binary neutron stars with double-spin effects

TL;DR

This paper introduces two advanced frequency-domain gravitational waveform models for binary neutron star mergers, incorporating matter effects and double-spin precession, offering improved efficiency and accuracy for gravitational wave data analysis.

Contribution

The paper presents the first extensions of IMRPhenomX models including matter effects and detailed precession dynamics with double-spin effects for binary neutron stars.

Findings

Models are more efficient and accurate than previous versions.

New precession descriptions better match numerical relativity simulations.

Models are suitable for Bayesian parameter estimation of future detections.

Abstract

We present two new frequency-domain gravitational waveform models for the analysis of signals emitted by binary neutron star coalescences: IMRPhenomXAS_NRTidalv2 and IMRPhenomXP_NRTidalv2. Both models are available through the public algorithm library LALSuite and represent the first extensions of IMRPhenomX models including matter effects. We show here that these two models represent a significant advancement in efficiency and accuracy with respect to their phenomenological predecessors, IMRPhenomD_NRTidalv2 and IMRPhenomPv2_NRTidalv2. The computational efficiency of the new models is achieved through the application of the same multibanding technique previously applied to binary black hole models. Furthermore, IMRPhenomXP_NRTidalv2 implements a more accurate description of the precession dynamics, including double-spin effects and, optionally, matter effects in the twisting-up construction. The latter are available through an option to use a numerical integration of the post-Newtonian precession equations. We show that the new precession descriptions allow the model to better reproduce the phenomenology observed in numerical-relativity simulations of precessing binary neutron stars. Finally, we present some applications of the new models to Bayesian parameter estimation studies, including a reanalysis of GW170817 and a study of simulated observations using numerical relativity waveforms for nonprecessing binary neutron stars with highly spinning components. We find that in these cases the new models make a negligible difference in the results. Nevertheless, by virtue of the aforementioned improvements, the new models represent valuable tools for the study of future detections of coalescing binary neutron stars.