📝 SummarXiv

Abstract

The mass ratio q and effective inspiral spin chi_eff of binary black hole mergers in GWTC-4.0 have been reported to display a weakeran ti-correlation compared to GWTC-3, a feature whose origin has been explored by several groups. In this work, within the isolated binary evolution framework, we adopt a recently proposed wind prescription for helium stars to systematically investigate the spin of the second-born black hole and its role in shaping this correlation. Using the stellar and binary evolution code MESA, which includes a recently proposed helium-star wind prescription alongside internal differential rotation and tidal interactions,we find that the recently proposed wind prescription for helium stars is substantially weaker than the standard Dutch wind scheme, particularly at subsolar metallicity. Using this scheme, we perform detailed binary modeling of a helium star with a black hole companion. Our results show that the spin magnitude of the resulting black hole is insensitive to the helium star's evolutionary stage at the onset of tidal interactions or to the companion mass. Instead, wind mass loss plays the dominant role: more massive helium-star progenitors produce lower-spinning black holes. The initial stellar rotation has only a minor effect, especially under strong tidal coupling, consistent with the common assumption of orbital synchronization. Using the derived relation between the mass and spin of the second-born black hole, we find that the properties of most binary black holes in GWTC-4.0-specifically the mass ratio q and effective inspiral spin chi_eff-can be reproduced. We further show that the q-chi_eff correlation is sensitive to the assumed mass function (e.g., Gaussian and uniform distribution), displaying notable deviations from the Power-Law+Peak model.