Breaking bad degeneracies with Love relations: Improving gravitational-wave measurements through universal relations

TL;DR

This paper introduces a new method using universal Love relations to break the distance-inclination degeneracy in gravitational-wave measurements of binary neutron stars, enabling more precise parameter estimation and better understanding of neutron star properties.

Contribution

The authors develop and implement a novel parametrization based on binary Love relations that reduces degeneracies in gravitational-wave data analysis of neutron star mergers.

Findings

Up to 70% reduction in distance and inclination credible intervals at high SNRs.

Improved measurement of source-frame masses by up to 50%.

Enhanced ability to infer neutron star population properties and jet opening angles.

Abstract

The distance-inclination degeneracy limits gravitational-wave parameter estimation of compact binary mergers. Although the degeneracy can be partially broken by including higher-order modes or precession, these effects are suppressed in binary neutron stars. In this work, we implement a new parametrization of the tidal effects in the binary neutron-star waveform, exploiting the binary Love relations, that breaks the distance-inclination degeneracy. The binary Love relations prescribe the tidal deformability of a neutron star as a function of its source-frame mass in an equation-of-state insensitive way and, thus, allows direct measurement of the redshift of the source. If the cosmological parameters are assumed to be known, the redshift can be converted to a luminosity distance, and the distance-inclination degeneracy can thus be broken. We implement this new approach, studying a range of binary neutron-star observing scenarios using Bayesian parameter estimation on synthetic data. In the era of the third-generation detectors, for observations with signal-to-noise ratios ranging from 6 to 167, we forecast up to an $\sim70\%$ decrease in the $90\%$ credible interval of the distance and inclination and up to an $\sim50\%$ decrease in that of the source-frame component masses. For edge-on systems, our approach can result in moderate ($\sim50\%$) improvement in the measurements of distance and inclination for binaries with a signal-to-noise ratio as low as 10. This prescription can be used to better infer the source-frame masses and, hence, refine population properties of neutron stars, such as their maximum mass, impacting nuclear astrophysics. When combined with the search for electromagnetic counterpart observations, the work presented here can be used to put improved bounds on the opening angle of jets from binary neutron-star mergers.