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Paper   IPM / Particles%20And%20Accelerator / 16218
School of Particles and Accelerator
  Title:   Echoes from the abyss: a highly spinning black hole remnant for the binary neutron star merger GW170817
  Author(s): 
1.  Jahed Abedi
2.  N Afshordi
  Status:   Published
  Journal: JCAP
  No.:  11
  Vol.:  010
  Year:  2020
  Supported by:  IPM
  Abstract:
The first direct observation of a binary neutron star (BNS) merger was a watershed moment in multi-messenger astronomy. However, gravitational waves from GW170817 have only been observed prior to the BNS merger, but electromagnetic observations all follow the merger event. While post-merger gravitational wave signal in general relativity is too faint (given current detector sensitivities), here we present the first tentative detection of post-merger gravitational wave "echoes" from a highly spinning "black hole" remnant. The echoes may be expected in different models of quantum black holes that replace event horizons by exotic Planck-scale structure and tentative evidence for them has been found in binary black hole merger events. The fact that the echo frequency is suppressed by logM (in Planck units) puts it squarely in the LIGO sensitivity window, allowing us to build an optimal model-agnostic search strategy via cross-correlating the two detectors in frequency/time. We find a tentative detection of echoes at fechoâ??72 Hz, around 1.0 sec after the BNS merger, consistent with a 2.6-2.7 Mâ?? "black hole" remnant with dimensionless spin 0.84â??0.87. Accounting for all the "look-elsewhere" effects, we find a significance of 4.2Ï?, or a false alarm probability of 1.6Ã?10â??5, i.e. a similar cross-correlation within the expected frequency/time window after the merger cannot be found more than 4 times in 3 days. If confirmed, this finding will have significant consequences for both physics of quantum black holes and astrophysics of binary neutron star mergers [Note added: This result is independently confirmed by arXiv:1901.04138, who use the electromagnetic observations to infer tcoll=0.98+0.31â??0.26 sec for black hole formation].

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