Post-Newtonian SPH calculations of binary neutron star coalescence. III. Irrotational systems and gravitational wave spectra

TL;DR

This paper presents a new post-Newtonian SPH simulation method for irrotational binary neutron star mergers, analyzing gravitational wave signals and spectra to infer nuclear matter properties.

Contribution

Introduces a novel method for constructing accurate initial conditions for irrotational binary neutron stars in PN gravity and provides detailed GW analysis.

Findings

Irrotational mergers produce similar peak GW luminosities as corotating ones.

Irrotational mergers shed almost no mass to large distances.

PN effects create identifiable features in GW energy spectra.

Abstract

Using our new post-Newtonian (PN) smoothed particle hydrodynamics (SPH) code, we have studied numerically the mergers of neutron star binaries with irrotational initial configurations. Here we describe a new method for constructing numerically accurate initial conditions for irrotational binary systems with circular orbits in PN gravity. We then compute the 3D hydrodynamic evolution of these systems until the two stars have completely merged, and we determine the corresponding GW signals. We present results for systems with different binary mass ratios, and for neutron stars represented by polytropes with $\Gamma=2$ or $\Gamma=3$. Compared to mergers of corotating binaries, we find that irrotational binary mergers produce similar peak GW luminosities, but they shed almost no mass at all to large distances. The dependence of the GW signal on numerical resolution for calculations performed with N>10^5 SPH particles is extremely weak, and we find excellent agreement between runs utilizing N=10^5 and N=10^6 SPH particles (the largest SPH calculation ever performed to study such irrotational binary mergers). We also compute GW energy spectra based on all calculations reported here and in our previous works. We find that PN effects lead to clearly identifiable features in the GW energy spectrum of binary neutron star mergers, which may yield important information about the nuclear equation of state at extreme densities.