The Analogous Structure of Accretion Flows in Supermassive and Stellar Mass Black Holes

John J. Ruan, Scott F. Anderson, Michael Eracleous, Paul J. Green, Daryl Haggard, Chelsea L. MacLeod, Jessie C. Runnoe, Malgosia Sobolewska

Published 2019-03-06Version 1

Black holes grow rapidly through the accretion of gas. As the accretion rate onto a black hole decreases, the structure of its surrounding accretion flow is believed to dramatically transition from a luminous thin disc to become quasi-spherical and radiatively inefficient. These accretion state transitions are commonly observed for stellar mass black holes in Galactic X-ray binary systems, but it is unknown if this process occurs similarly for supermassive black holes at the centres of galaxies. Here, we show that the geometry of the accretion flow around supermassive and stellar mass black holes evolve analogously during transitions between different accretion states. We use X-ray and rest-UV observations of faded 'changing-look' quasars to probe the geometry of the feeble accretion flows around their supermassive black holes, based on the spectral changes as a function of Eddington ratio. We find that the observed spectral evolution in fading quasars displays a remarkable similarity to accretion state transitions in X-ray binary outbursts. Our results show that the structures of black hole accretion flows directly scales across a factor of 10^8 in black hole mass, and enables us to apply theoretical models of X-ray binaries to explain active galactic nuclei phenomenology.