Modeling Magnetic Disk-Wind State Transitions in Black Hole X-ray Binaries

Abstract

We analyze three prototypical black hole (BH) X-ray binaries (XRBs), \4u1630, 1655\ and 1743, in an effort to systematically understand the intrinsic state transition of the observed accretion-disk winds between \ and \ states by utilizing state-of-the-art Chandra/HETGS archival data from multi-epoch observations. We apply our magnetically-driven wind models in the context of magnetohydrodynamic (MHD) calculations to constrain their (1) global density slope (p), (2) their density (n17) at the foot point of the innermost launching radius and (3) the abundances of heavier elements (A Fe,S,Si). Incorporating the MHD winds into xstar photoionization calculations in a self-consistent manner, we create a library of synthetic absorption spectra given the observed X-ray continua. Our analysis clearly indicates a characteristic bi-modal transition of multi-ion X-ray winds; i.e. the wind density gradient is found to steepen (from p 1.2-1.4 to 1.4-1.5) while its density normalization declines as the source transitions from \ to \ state. The model implies that the ionized wind remains physically present even in \ state, despite its absent appearance in the observed spectra. Super-solar abundances for heavier elements are also favored. Our global multi-ion wind models, taking into account soft X-ray ions as well as Fe K absorbers, show that the internal wind condition plays an important role in wind transitions besides photoionization changes. % Simulated XRISM/Resolve and Athena/X-IFU spectra are presented to demonstrate a high fidelity of the multi-ion wind model for better understanding of these powerful ionized winds in the coming decades.