http://arxiv.org/abs/1706.07053
The Advanced LIGO has observed four BH-BH mergers thus far. The effective spin of GW170104 has an 82 percent probability of being negative, which would indicate spin-orbit misalignment. It has been suggested that LIGO’s detections favor a population of binaries with frequent and significant spin-orbit misalignment, hence supporting dynamical formation over classical isolated binary evolution. However, it is also well known that massive stars can have efficient transport of angular momentum within the star and have strong winds that carry away substantial angular momentum. The progenitors of the heaviest stellar-mass BHs (M>30Msun) are expected to efficiently reduce their angular momentum, producing BHs with low spin (consistent with existing LIGO constraints). A stellar evolution model that incorporates rotation is used to determine the natal spins of the BHs produced by core collapse. These natal spins are incorporated into our population synthesis code which follows the evolution of Population I/II stars across cosmic time and predicts the BH-BH population in the universe. Our classical isolated binary evolution model produces a BH-BH population that is consistent with the observed LIGO population. In particular, it produces systems that are consistent with the measured properties of GW170104; total mass, mass ratio, effective spin and the overall BH-BH merger rate. Neither strong natal BH kicks nor dynamical interactions are required to recover GW170104. LIGO’s observations do not provide evidence for dynamical formation over classical isolated binary formation and it is not yet possible to establish the evolutionary channel through which GW170104 was formed.
K. Belczynski, J. Klencki, G. Meynet, et. al.
Fri, 23 Jun 17
3/48
Comments: to be submitted to A&A (comments welcome)