Abstract
Advanced LIGO-Virgo have reported a short gravitational-wave signal (GW190521) interpreted as a quasicircular merger of black holes, one at least populating the pair-instability supernova gap, that formed a remnant black hole of M_{f}∼142 M_{⊙} at a luminosity distance of d_{L}∼5.3 Gpc. With barely visible pre-merger emission, however, GW190521 merits further investigation of the pre-merger dynamics and even of the very nature of the colliding objects. We show that GW190521 is consistent with numerically simulated signals from head-on collisions of two (equal mass and spin) horizonless vector boson stars (aka Proca stars), forming a final black hole with M_{f}=231_{-17}^{+13} M_{⊙}, located at a distance of d_{L}=571_{-181}^{+348} Mpc. This provides the first demonstration of close degeneracy between these two theoretical models, for a real gravitational-wave event. The favored mass for the ultralight vector boson constituent of the Proca stars is μ_{V}=8.72_{-0.82}^{+0.73}×10^{-13} eV. Confirmation of the Proca star interpretation, which we find statistically slightly preferred, would provide the first evidence for a long sought dark matter particle.
Highlights
Advanced LIGO-Virgo have reported a short gravitational-wave signal (GW190521) interpreted as a quasicircular merger of black holes, one at least populating the pair-instability supernova gap, that formed a remnant black hole of Mf ∼ 142 M⊙ at a luminosity distance of dL ∼ 5.3 Gpc
We show that GW190521 is consistent with numerically simulated signals from head-on collisions of two horizonless vector boson stars, forming a final black hole with Mf 1⁄4 231þ−1173 M⊙, located at a distance of dL 1⁄4 571þ−138418 Mpc
Introduction.—Gravitational-wave (GW) astronomy has revealed stellar-mass black holes (BHs) more massive than those known from x-ray observations [1,2]
Summary
Advanced LIGO-Virgo have reported a short gravitational-wave signal (GW190521) interpreted as a quasicircular merger of black holes, one at least populating the pair-instability supernova gap, that formed a remnant black hole of Mf ∼ 142 M⊙ at a luminosity distance of dL ∼ 5.3 Gpc. We show that GW190521 is consistent with numerically simulated signals from head-on collisions of two (equal mass and spin) horizonless vector boson stars (aka Proca stars), forming a final black hole with Mf 1⁄4 231þ−1173 M⊙, located at a distance of dL 1⁄4 571þ−138418 Mpc. This provides the first demonstration of close degeneracy between these two theoretical models, for a real gravitational-wave event.
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