# Simulating Binary Neutron Stars with Hybrid Equation of States:   Gravitational Waves, Electromagnetic Signatures, and Challenges for Numerical   Relativity

**Authors:** Henrique Gieg, Tim Dietrich, Maximiliano Ujevic

arXiv: 1908.03135 · 2019-08-09

## TL;DR

This paper explores how strange quark matter cores in neutron stars influence gravitational wave signals and electromagnetic signatures during mergers, highlighting numerical challenges and implications for interpreting GW170817 data.

## Contribution

It introduces numerical relativity simulations of neutron star mergers with hybrid equations of state including strange quark matter, analyzing their gravitational and electromagnetic signatures.

## Key findings

- Strong phase transitions affect numerical convergence order.
- Existing waveform models are adequate within uncertainties but require higher resolution.
- Electromagnetic signatures in the studied setup are too faint to explain GW170817's kilonova.

## Abstract

The gravitational wave and electromagnetic signatures connected to the merger of two neutron stars allow us to test the nature of matter at supranuclear densities. Since the Equation of State governing the interior of neutron stars is only loosely constrained, there is even the possibility that strange quark matter exists inside the core of neutron stars. We investigate how strange quark matter cores affect the binary neutron star coalescence by performing numerical relativity simulations. Interestingly, the strong phase transition can cause a reduction of the convergence order of the numerical schemes to first order if the numerical resolution is not high enough. Therefore, an additional challenge is added in producing high-quality gravitational wave templates for Equation of States with a strong phase transition. Focusing on one particular configuration of an equal mass configuration consistent with GW170817, we compute and discuss the associated gravitational wave signal and some of the electromagnetic counterparts connected to the merger of the two stars. We find that existing waveform approximants employed for the analysis of GW170817 allow describing this kind of systems within the numerical uncertainties, which, however, are several times larger than for pure hadronic Equation of States, which means that even higher resolutions have been employed for an accurate gravitational wave model comparison. We also show that for the chosen Equation of State, quasi-universal relations describing the gravitational wave emission after the moment of merger seem to hold and that the electromagnetic signatures connected to our chosen setup would not be bright enough to explain the kilonova associated to GW170817.

## Full text

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## Figures

16 figures with captions in the complete paper: https://tomesphere.com/paper/1908.03135/full.md

## References

101 references — full list in the complete paper: https://tomesphere.com/paper/1908.03135/full.md

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Source: https://tomesphere.com/paper/1908.03135