Black hole spectroscopy horizons for current and future gravitational wave detectors

TL;DR

This paper evaluates the detectability of multiple quasinormal modes in black hole mergers using gravitational wave data, proposing a conservative Bayesian approach to define spectroscopy horizons for current and future detectors.

Contribution

It introduces a Bayesian threshold method for black hole spectroscopy horizons, improving upon the traditional Rayleigh criterion, and provides detailed predictions for detection rates with LIGO and Cosmic Explorer.

Findings

High Bayes factor thresholds are more effective than Rayleigh criterion for mode detection.

Detection horizons vary with binary mass and mode type, favoring certain subdominant modes.

Predicted event rates suggest feasible black hole spectroscopy with future detectors.

Abstract

Black hole spectroscopy is the proposal to observe multiple quasinormal modes in the ringdown of a binary black hole merger. In addition to the fundamental quadrupolar mode, overtones and higher harmonics may be present and detectable in the gravitational wave signal, allowing for tests of the no-hair theorem. We analyze in detail the strengths and weaknesses of the standard Rayleigh criterion supplied with a Fisher matrix error estimation, and we find that the criterion is useful, but too restrictive. Therefore we motivate the use of a conservative high Bayes factor threshold to obtain the black hole spectroscopy horizons of current and future detectors, i.e., the distance (averaged in sky location and binary inclination) up to which one or more additional modes can be detected and confidently distinguished from each other. We set up all of our searches for additional modes starting at $t = 10(M_1+M_2)$ after the peak amplitude in simulated signals of circular nonspinning binaries. An agnostic multimode analysis allows us to rank the subdominant modes: for nearly equal mass binaries we find $(\ell, m, n) = (2,2,1)$ and $(3,3,0)$ and, for very asymmetric binaries, $(3,3,0)$ and $(4,4,0)$, for the secondary and tertiary modes, respectively. At the current estimated rates for heavy stellar mass binary black hole mergers, with primary masses between 45 and 100 solar masses, we expect an event rate of mergers within our conservative estimate for the $(2,2,1)$ spectroscopy horizon of $0.03 - 0.10\ {\rm yr}^{-1}$ for LIGO at design sensitivity and $(0.6 - 2.4) \times 10^3\ {\rm yr}^{-1}$ for the future third generation ground-based detector Cosmic Explorer.