Directly inferring cosmology and the neutron-star equation of state from gravitational-wave mergers

Abstract

Upgrades to existing gravitational-wave observatories have the potential to simultaneously constrain the nuclear equation of state and Hubble's constant H0 to percent level with merging neutron star binaries. In practice, performing simultaneous inference of H0 and the equation of state is limited computationally by the requirement to solve the equations of general-relativistic hydrostatic equilibrium millions of times. We develop a machine-learning model to solve the Tolman-Oppenheimer-Volkoff equations in less than a millisecond, and demonstrate its utility by performing direct inference of both equation of state and Hubble's constant for synthetic neutron star merger signals with LIGO-Virgo-KAGRA operating at A+ sensitivities. We show that a population of fifteen mergers observed with A+ allows for the radius of a 1.4\,M neutron star and H0 to be constrained to R1.4 = 11.74+0.35-0.28 km and H0 = 68+17-13 \ km \ s-1 \ Mpc-1, at 90% credible interval and 68% credible interval respectively. These constraints utilise only the gravitational-wave information to infer cosmological parameters; such numbers will be further improved with the addition of electromagnetic counterparts and/or galaxy catalogues.

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