A Phase Lag between Disk and Corona in GRMHD Simulations of Precessing Tilted Accretion Disks

Abstract

In the course of its evolution, a black hole (BH) accretes gas from a wide range of directions. Given a random accretion event, the typical angular momentum of an accretion disc would be tilted by 60 relative to the BH spin. Misalignment causes the disc to precess at a rate that increases with BH spin and tilt angle. We present the first general-relativistic magnetohydrodynamic (GRMHD) simulations spanning a full precession period of highly tilted (60), moderately thin (h/r=0.1) accretion discs around a rapidly spinning (a0.9) BH. While the disc and jets precess in phase, we find that the corona, sandwiched between the two, lags behind by 10. For spectral models of BH accretion, the implication is that hard non-thermal (corona) emission lags behind the softer (disc) emission, thus potentially explaining some properties of the hard energy lags seen in Type-C low frequency quasi-periodic oscillations in X-Ray binaries. While strong jets are unaffected by this disc-corona lag, weak jets stall when encountering the lagging corona at distances r 100 black hole radii. This interaction may quench large-scale jet formation.