Jets from neutron-star merger remnants and massive blue kilonovae

Abstract

We perform high-resolution three-dimensional general-relativistic magnetohydrodynamic simulations with neutrino transport of binary neutron star (BNS) mergers resulting in a long-lived remnant neutron star, with properties typical of galactic BNS and consistent with those inferred for the first observed BNS merger GW170817. We demonstrate self-consistently that within \!30 ms post-merger magnetized (σ 5-10) twin polar jets emerge with asymptotic Lorentz factor 5-10, which successfully break out from the merger debris within \!20 ms. A fast (v 0.6c), magnetized (σ 0.1) wind surrounds the jet core and generates a UV/blue kilonova precursor on timescales of hours, similar to the precursor signal due to free neutron decay in fast dynamical ejecta. Post-merger ejecta are quickly dominated by MHD-driven outflows from an accretion disk. We demonstrate that within only 50 ms post-merger, 2× 10-2M of lanthanide-free, quasi-spherical ejecta with velocity \!0.1c is launched, yielding a kilonova signal consistent with GW170817 on timescales of \!5\,d.