Jet-like Structures in Low-mass Binary Neutron Star Merger Remnants

University of Illinois at Urbana-Champaign

Abstract

GW170817 and GRB 170817A provided direct evidence that binary neutron star (NSNS) mergers can produce short gamma-ray bursts (sGRBs). However, questions remain about the nature of the central engine. Depending on the mass, the remnant from a NSNS merger may promptly collapse to a black hole (BH), form a hypermassive neutron star (HMNS) which undergoes a delayed collapse to a BH, a supramassive neutron star (SMNS) with a much longer lifetime, or an indefinitely stable NS. There is strong evidence that a BH with an accretion disk can launch a sGRB-compatible jet via the Blandford-Znajek mechanism, but whether a supramassive star can do the same is less clear. We have performed general relativistic magnetohydrodynamics (GRMHD) simulations of the merger of both irrotational and spinning, equal-mass NSNSs constructed from a piecewise polytropic representation of the SLy equation of state, with a range of gravitational (ADM) masses that yield remnants with mass above and below the supramassive limit. Each NS is endowed with a dipolar magnetic field extending from the interior into the exterior, as in a radio pulsar. We examine cases with different initial binary masses, including a case which produces a HMNS that collapses to a BH, and lower mass binaries that produce SMNS remnants. We find similar jet-like structures for both the SMNS and HMNS remnants that meet our basic critera for an incipient jet. The outflow for the HMNS case is consistent with a Blandford-Znajek (BZ) jet. There is sufficient evidence that such BZ-powered outflows can break out and produce ulrarelativistic jets so that we can describe the HMNS system as a sGRB progenitor. However, the incipient jets from the SMNS remnants have much more baryon pollution and we see indications of inefficient acceleration and mixing with the surrounding debris. Therefore, we cannot conclude that SMNS outflows are the progenitors of sGRBs.

arXiv:2405.03705

Rendering

These visualizations were created using VisIt software on the Anvil supercomputer at Purdue and Riemann at UIUC. Some of the cases include movies for evolution and gravity waves.


University of Illinois at Urbana-Champaign

Introduction
Initial Configuration
Irrotational Cases
Case A1: Mass = 2.40 M*
Case B1: Mass = 2.51 M
Case C1: Mass = 2.54 M*
Case D1: Mass = 2.57 M*
Case E1: Mass = 2.70 M (BH Remnant)*
Spinning Cases
Case A2: Mass = 2.40 M
Case B2: Mass = 2.51 M*
Case C2: Mass = 2.54 M
Case D2: Mass = 2.57 M*

*Cases with movies on both density evolution and gravity waves