Joint Inference of Population, Cosmology, and Neutron Star Equation of State from Gravitational Waves of Dark Binary Neutron Stars

Gravitational waves (GWs) from binary neutron stars (BNSs) are expected to be accompanied by electromagnetic (EM) emissions, which help to identify the host galaxy. Since GW events directly measure their luminosity distances, joint GW-EM observations from BNSs help to study cosmology, particularly the Hubble constant, unaffected by cosmic distance ladder systematics. However, detecting EM counterparts from BNS mergers is not always possible. Additionally, the tidal deformations of BNS components offer insights into the neutron star (NS) equation of state (EoS). In such cases, the tidal parameters of NSs, combined with the knowledge of the NS EoS, can break the degeneracy between mass parameters and redshift, allowing for the inference of the Hubble constant. Several efforts have aimed to infer the Hubble constant using the tidal parameters of BNSs, without EM counterparts, termed dark BNSs. Moreover, some studies have focused on the joint estimation of population and NS EoS for unbiased NS EoS estimation. However, none of the works consistently combined the uncertainties of population, cosmology, and NS EoS within a Bayesian framework. In this study, we propose a novel Bayesian analysis to jointly constrain the NS EoS, population, and cosmological parameters using a population of dark BNSs detected through GW observations. This method can well constrain the Hubble constant with as few as $5$ BNS observations using current-generation detectors. This level of precision is unattainable without incorporating the NS EoS, especially when observing BNS mergers without EM counterpart information.
Comment: 26 pages, 14 figures, 4 tables