The detection of Quasinormal Mode of Pop III Binary Black Hole merger with final M 60M and a/M 0.7 would confirm the strong gravity space-time around 2M which is only 1.17 times the event horizon radius

Abstract

Recent population synthesis simulations of Pop III stars suggest that the event rate of coalescence of 30M--30M binary black holes can be high enough for the detection by the second generation gravitational wave detectors. The frequencies of chirp signal as well as quasinormal modes are near the best sensitivity of these detectors so that it would be possible to confirm Einstein's general relativity. Using the WKB method, we suggest that for the typical value of spin parameter a/M 0.7 from numerical relativity results of the coalescence of binary black holes, the strong gravity of the black hole space-time at around the radius 2M, which is just 1.17 times the event horizon radius, would be confirmed as predicted by general relativity. The expected event rate with the signal-to-noise ratio > 35 needed for the determination of the quasinormal mode frequency with the meaningful accuracy is 0.17--7.2~ events~yr-1~(SFRp/(10-2.5~M~yr-1~Mpc-3)) · ( [fb/(1+fb)]/0.33) where SFRp and fb are the peak value of the Pop III star formation rate and the fraction of binaries, respectively. As for the possible optical counter part, if the merged black hole of mass M 60M is in the interstellar matter with n 100~ cm-3 and the proper motion of black hole is 1~ km~s-1, the luminosity is 1040~ erg~ s-1 which can be detected up to 300~ Mpc, for example, by Subaru-HSC and LSST with the limiting magnitude 26.