Spins of Black Holes in X-ray Binaries and the Tension with the Gravitational Wave Measurements (2506.00623v1)

Abstract: We review current challenges in understanding the values and origin of the spins of black holes in binaries. A key finding of the gravitational-wave observatories is that premerger black holes in binaries have low spin values, with an average dimensionless spin parameter of $a_\sim$0.1-0.2. Furthermore, the spins in the first-born black holes appear lower than in the second-born ones. This implies that the natal spins of black holes are generally low, and the angular momentum transport in massive stars is efficient. On the other hand, most of the published spins in X-ray binaries are very high, $a_\gtrsim 0.7$. This is the case, in particular, for binaries with high-mass donors (potential progenitors of mergers), where their published spins range from 0.8 to 1.0, while their short lifetimes prevent significant spin-up by accretion. Those with low-mass donors could be spun-up to $a_*\gtrsim 0.7$ by accretion, but only if the donor initial masses were more than several solar masses, which remains unproven. However, we find the existing methods of spin measurements suffer from significant systematic errors. The method relying on relativistic X-ray line broadening is based on the separation of the observed spectra into the incident and reflected ones, which is intrinsically highly uncertain. The method of spectral fitting accretion disk continua uses models that predict the disk to be highly unstable, while stability is observed. Improved stable models give the disk temperatures higher than the standard models, and consequently predict lower spins. We postulate that the published spin measurements in X-ray binaries are uncertain. We hypothesize that the spins of the binaries with high-mass donors are low, while those with low-mass donors have a broader spin distribution, ranging from low to high, including high spins as required to power relativistic jets.