Formation of Stable Magnetars from Binary Neutron Star Mergers

TL;DR

This study uses advanced simulations to demonstrate that certain binary neutron star mergers can produce stable, highly magnetized neutron stars (magnetars) with potential implications for gravitational wave and gamma-ray burst observations.

Contribution

The paper shows that binary neutron star mergers can result in stable, ultraspinning magnetars with strong magnetic fields, expanding understanding of post-merger remnants.

Findings

Merger products can be stable, differentially rotating neutron stars.

Magnetic fields can be amplified to magnetar levels.

Formation of magnetar surrounded by an accretion disk is possible.

Abstract

By performing fully general relativistic magnetohydrodynamic simulations of binary neutron star mergers, we investigate the possibility that the end result of the merger is a stable magnetar. In particular, we show that, for a binary composed of two equal-mass neutron stars (NSs) of gravitational mass M~1.2 Msun and equation of state similar to Shen et al. at high densities, the merger product is a stable NS. Such NS is found to be differentially rotating and ultraspinning with spin parameter J/M^2~0.86, where J is its total angular momentum, and it is surrounded by a disk of ~0.1 Msun. While in our global simulations the magnetic field is amplified by about two orders of magnitude, local simulations have shown that hydrodynamic instabilities and the onset of the magnetorotational instability could further increase the magnetic field strength up to magnetar levels. This leads to the interesting possibility that, for some NS mergers, a stable and magnetized NS surrounded by an accretion disk could be formed. We discuss the impact of these new results for the emission of electromagnetic counterparts of gravitational wave signals and for the central engine of short gamma-ray bursts.