When can gravitational-wave observations distinguish between black holes and neutron stars?

TL;DR

This paper analyzes the conditions under which gravitational-wave observations can reliably distinguish between black holes and neutron stars, considering parameter degeneracies and observational limitations.

Contribution

It identifies specific mass ranges where component types can be unambiguously determined and discusses how electromagnetic counterparts can aid in constraining black-hole spins.

Findings

Mass ranges for unambiguous identification of neutron stars and black holes.

Degeneracy between mass ratio and angular momentum limits parameter estimation.

Electromagnetic observations can help constrain black-hole spins.

Abstract

Gravitational-wave observations of compact binaries have the potential to uncover the distribution of masses and angular momenta of black holes and neutron stars in the universe. The binary components' physical parameters can be inferred from their effect on the phasing of the gravitational-wave signal, but a partial degeneracy between the components' mass ratio and their angular momenta limits our ability to measure the individual component masses. At the typical signal amplitudes expected by the Advanced Laser Interferometer Gravitational-wave Observatory (signal-to-noise ratios between 10 and 20), we show that it will in many cases be difficult to distinguish whether the components are neutron stars or black holes. We identify when the masses of the binary components could be unambiguously measured outside the range of current observations: a system with a chirp mass $\mathcal{M} \le 0.871 $ M$_\odot$ would unambiguously contain the smallest-mass neutron star observed, and a system with $\mathcal{M} \ge 2.786 \Msun$ must contain a black hole. However, additional information would be needed to distinguish between a binary containing two 1.35 M$_\odot$ neutron stars and an exotic neutron-star--black-hole binary. We also identify those configurations that could be unambiguously identified as black-hole binaries, and show how the observation of an electromagnetic counterpart to a neutron-star--black-hole binary could be used to constrain the black-hole spin.