Model-Independent Determination of the Tidal Deformability of a 1.4 M Neutron Star from Gravitational-Wave Measurements

Abstract

Tidal deformability of a 1.4 M neutron star provides a pivotal window into the physics of dense nuclear matter, bridging gravitational-wave(GW), electromagnetic observations and nuclear physics. In this work, we present a novel, data-driven approach to constrain 1.4 without invoking specific equation-of-state(EOS) models. By interpolating directly over the mass--tidal-deformability posteriors from GW170817, we obtain an EOS-independent constraint of 1.4 \;=\; 222.89-98.85+420.33. We further combine these GW-based results with the X-ray EOS-independent constraint from Huang2025, deriving a multimessenger limit of 1.4 \;=\; 265.18-104.38+237.88, which remains largely EOS agnostic. This framework demonstrates that higher-order terms neglected in linear expansion methods do not significantly affect 1.4 estimates under current observational uncertainties. As gravitational-wave detectors improve in sensitivity and more binary neutron-star mergers are discovered, our purely data-driven strategy can serve as a robust standard baseline for extracting neutron-star interior properties without relying on unverified EOS models.