Divergence in mass ratio distributions between low-mass and high-mass coalescing binary black holes

Abstract

Coalescing binary black hole (BBH) systems are likely formed via several channels, and it is challenging to understand their formation / evolutionary processes. Some features in the mass function of the primary components (m1), such as the distinct Gaussian-like peak located at 34M, have been previously found. In this work, we investigate the possible dependence of the mass ratio (q=m2/m1) distribution on the primary mass. We find a Bayesian odds ratio of 18.1 in favor of divergence in the mass ratio distributions between the low- and high-mass ranges over an invariable mass ratio distribution. The BBHs with m129M have a stronger preference to be symmetric compared to those with m129M at a 97.6\% credible level. Additionally, we find mild evidence that the BBHs with m1 located in the Gaussian-like peak have a mass ratio distribution different from that of other BBHs. Our findings may be in favor of some formation channels, such as the chemically homogeneous evolution and the dynamical assembly in globular clusters/nuclear star clusters, which are more likely to provide symmetric BBHs in the high-mass range.