Abstract
The first multimessenger observation attributed to a merging neutron star binary provided an enormous amount of observational data. Unlocking the full potential of this data requires a better understanding of the merger process and the early post-merger phase, which are crucial for the later evolution that eventually leads to observable counterparts. In this work, we perform standard hydrodynamical numerical simulations of a system compatible with GW170817. We focus on a single equation of state (EOS) and two mass ratios, while neglecting magnetic fields and neutrino radiation. We then apply newly developed postprocessing and visualization techniques to the results obtained for this basic setting. The focus lies on understanding the three-dimensional structure of the remnant, most notably the fluid flow pattern, and its evolution until collapse. We investigate the evolution of mass and angular momentum distribution up to collapse, as well as the differential rotation along and perpendicular to the equatorial plane. For the cases that we studied, the remnant cannot be adequately modeled as a differentially rotating axisymetric NS. Further, the dominant aspect leading to collapse is the GW radiation and not internal redistribution of angular momentum. We relate features of the gravitational wave signal to the evolution of the merger remnant, and make the waveforms publicly available. Finally, we find that the three-dimensional vorticity field inside the disk is dominated by medium-scale perturbances and not the orbital velocity, with potential consequences for magnetic field amplification effects.
Highlights
This work is motivated by the first multimessenger detection compatible with the coalescence of two neutron stars (NSs)
The coalescing NS merge into a hypermassive NS (HMNS), which collapses to a black hole (BH) after a delay on the order of ≈10 ms
In order to get an estimate of the angular momentum transport inside the remnant, we study the integrands of the Arnowitt– Deser–Misner (ADM) volume integrals
Summary
This work is motivated by the first multimessenger detection compatible with the coalescence of two neutron stars (NSs). After a delay around 1.7 s, the GW signal was followed by short gamma ray burst (SGRB) event GRB170817A observed by Fermi and INTEGRAL satellites and attributed to the same source [3]. Later observations revealed radio signals [4,5] that likely correspond to the radio afterglow of the SGRB. The coincident GW and SGRB events triggered a large observational follow-up campaign [6]. Observations ranging from infrared to ultraviolet revealed an optical counterpart AT2017gfo with luminosity and spectral evolution compatible with a kilonova [6,7,8,9]
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