Electromagnetic Signatures from the Tidal Tail of a Black Hole-Neutron Star Merger
Abstract
Black hole-neutron star (BH-NS) mergers are a major target for ground-based gravitational wave observatories. A merger can also produce an electromagnetic counterpart (a kilonova) if it ejects neutron-rich matter that assembles into heavy elements through r-process nucleosynthesis. We study the kilonova signatures of the unbound dynamical ejecta of a BH-NS merger. We take as our initial state the results from a numerical relativity simulation and then use a general relativistic hydrodynamics code to study the evolution of the ejecta with parameterized r-process heating models. The unbound dynamical ejecta is initially a flattened, directed tidal tail largely confined to a plane. Heating from the r-process inflates the ejecta into a more spherical shape and smooths its small-scale structure, though the ejecta retains its bulk directed motion. We calculate the electromagnetic signatures using a 3D radiative transfer code and a parameterized opacity model for lanthanide-rich matter. The light curve varies with viewing angle because of two effects: asphericity results in brighter emission for orientations with larger projected areas, while Doppler boosting results in brighter emission for viewing angles more aligned with the direction of bulk motion. For typical r-process heating rates, the peak bolometric luminosity varies by a factor of ~3 with orientation while the peak in the optical bands varies by ~3 magnitudes. The spectrum is blueshifted at viewing angles along the bulk motion, which increases the V-band peak magnitude to ~-14 despite the lanthanide-rich composition.
- Publication:
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The Astrophysical Journal
- Pub Date:
- July 2021
- DOI:
- arXiv:
- arXiv:2103.03378
- Bibcode:
- 2021ApJ...915...69D
- Keywords:
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- Stellar mass black holes;
- Neutron stars;
- Transient sources;
- R-process;
- Hydrodynamical simulations;
- Radiative transfer simulations;
- 1611;
- 1108;
- 1851;
- 1324;
- 767;
- 1967;
- Astrophysics - High Energy Astrophysical Phenomena
- E-Print:
- 26 pages, 15 figures