Inferring neutron star properties with continuous gravitational waves

Detection of continuous gravitational waves from rapidly spinning neutron stars opens up the possibility of examining their internal physics. We develop a framework that leverages a future continuous gravitational wave detection to infer a neutron star's moment of inertia, equatorial ellipticity, and the component of the magnetic dipole moment perpendicular to its rotation axis. We assume that the neutron star loses rotational kinetic energy through both gravitational wave and electromagnetic radiation, and that the distance to the neutron star can be measured, but do not assume electromagnetic pulsations are observable or a particular neutron star equation of state. We use the Fisher information matrix and Monte Carlo simulations to estimate errors in the inferred parameters, assuming a population of gravitational-wave-emitting neutron stars consistent with the typical parameter domains of continuous gravitational wave searches. After an observation time of 1 yr, the inferred errors for many neutron stars are limited chiefly by the error in the distance to the star. The techniques developed here will be useful if continuous gravitational waves are detected from a radio, X-ray, or gamma-ray pulsar, or else from a compact object with known distance, such as a supernova remnant.

Automated summary

Detection of continuous gravitational waves allows us to study the internal physics of rapidly spinning neutron stars. We propose a framework that uses future continuous gravitational wave detection to infer important parameters of neutron stars, such as their moment of inertia and magnetic dipole moment. By utilizing the Fisher information matrix and Monte Carlo simulations, we estimate the errors in the inferred parameters, providing valuable insights for continuous gravitational wave searches.