A long-lived remnant neutron star after GW170817 inferred from its associated kilonova

TL;DR

This paper proposes a model where a long-lived neutron star remnant from GW170817 powered the late-time kilonova emission, providing insights into neutron star physics and the merger process.

Contribution

It introduces a hybrid energy source model for the kilonova AT2017gfo, suggesting a long-lived remnant neutron star was formed during GW170817, which influences late emission.

Findings

Late kilonova emission is mainly powered by the remnant NS.

A single opacity value of ~0.97 cm^2/g fits the data.

The remnant NS indicates a very stiff equation of state.

Abstract

The successful joint observation of the gravitational wave event GW170817 and its multi-wavelength electromagnetic counterparts first enables human to witness a definite merger event of two neutron stars (NSs). This historical event confirms the origin of short-duration gamma-ray bursts (GRBs), and in particular, identifies the theoretically-predicted kilonova phenomenon that is powered by radioactive decays of $r$-process heavy elements. However, whether a long-lived remnant NS could be formed during this merger event remains unknown, although such a central engine has been suggested by afterglow observations of some short-duration GRBs. By invoking this long-lived remnant NS, we here propose a model of hybrid energy sources for the kilonova AT2017gfo associated with GW 170817. While the early emission of AT2017gfo is still powered radioactively as usually suggested, its late emission is primarily caused by delayed energy injection from the remnant NS. In our model, only one single opacity is required and an intermediate value of $\kappa\simeq0.97\,\rm cm^2g^{-1}$ is revealed, which could be naturally provided by lanthanide-rich ejecta that is deeply ionized by the emission from a wind of the NS. These self-consistent results indicate that a long-lived remnant NS, which must own a very stiff equation of state, had been formed during the merger event of GW170817. This provides a very stringent constraint on the strong interaction in nuclear-quark matter. It is further implied that such GW events could provide a probe of the early spin and magnetic evolutions of NSs, e.g., the burying of surface magnetic fields.