Merging binary black holes formed through chemically homogeneous evolution in short-period stellar binaries

TL;DR

This paper investigates a novel stellar evolution pathway where chemically homogeneous evolution in tight binaries leads to binary black hole mergers, predicting rates comparable to other channels and distinctive high-mass, equal-mass systems.

Contribution

It introduces and models a new formation channel for binary black holes via chemically homogeneous evolution in short-period binaries, with estimated merger rates and observable characteristics.

Findings

Estimated local merger rate of ~10 Gpc$^{-3}$ yr$^{-1}$

Predicted high-mass, nearly equal-mass black hole binaries

Low likelihood of high-redshift mergers due to short delay times

Abstract

We explore a newly proposed channel to create binary black holes of stellar origin. This scenario applies to massive, tight binaries where mixing induced by rotation and tides transports the products of hydrogen burning throughout the stellar envelopes. This slowly enriches the entire star with helium, preventing the build-up of an internal chemical gradient. The stars remain compact as they evolve nearly chemically homogeneously, eventually forming two black holes, which, we estimate, typically merge 4--11 Gyr after formation. Like other proposed channels, this evolutionary pathway suffers from significant theoretical uncertainties, but could be constrained in the near future by data from advanced ground-based gravitational-wave detectors. We perform Monte Carlo simulations of the expected merger rate over cosmic time to explore the implications and uncertainties. Our default model for this channel yields a local binary black hole merger rate of about $10$ Gpc$^{-3}$ yr$^{-1}$ at redshift $z=0$, peaking at twice this rate at $z=0.5$. This means that this channel is competitive, in terms of expected rates, with the conventional formation scenarios that involve a common-envelope phase during isolated binary evolution or dynamical interaction in a dense cluster. The events from this channel may be distinguished by the preference for nearly equal-mass components and high masses, with typical total masses between 50 and 110 $\textrm{M}_\odot$. Unlike the conventional isolated binary evolution scenario that involves shrinkage of the orbit during a common-envelope phase, short time delays are unlikely for this channel, implying that we do not expect mergers at high redshift.