Black Hole Olympics: Metric Selection from the Event Horizon Telescope and LIGO-VIRGO Observations

Abstract

We propose a new paradigm in the field of black hole physics, i.e., with more and more high precision observations, one must make a metric selection to determine which black hole is observationally preferred. In light of the shadow imaging data from the Event Horizon Telescope and gravitational wave measurements from the LIGO-VIRGO collaboration, we attempt to address this issue. Although not finding any obvious preference for a specific black hole metric based on current data, as a presentation of this new research paradigm, we rank these black hole metrics using the Bayesian information criterion. We find that Kerr and Reissner-Nordstr\"om tie the first place in the black hole Olympics Games. Interestingly, we give the 2\,σ upper bound of the average electronic charge Q<2.82×1018 C for the Reissner-Nordstr\"om spacetime, and the 2\,σ constraint on the average spin parameter a=-0.02+4.07-4.04 m for the Kerr spacetime, which is consistent with the prediction of zero rotation for a distant observer. Future multi-messenger and multi-wavelength observations will enhance the application of this new paradigm into tests of gravitational theories and black holes.