http://arxiv.org/abs/1707.06619
Gas falling into a black hole (BH) from large distances is unaware of the BH spin direction, and misalignment between the accretion disc and BH spin is expected to be common. However, the physics of such tilted discs (e.g., the angular momentum transport and ability to launch relativistic jets) is poorly understood. Using our new GPU-accelerated code H-AMR, we performed the highest-resolution (up to 1 billion cells) 3D general relativistic MHD simulations to date of tilted thick accretion discs around rapidly spinning BHs. We show for the first time that over a range in magnetic field strength these flows launch twin magnetized relativistic jets propagating along the rotation axis of the tilted disc (rather than of the BH). If strong large-scale magnetic flux reaches the BH, it can bend the inner few gravitational radii of the disc and jets into partial alignment with the BH spin. On longer time scales, the simulated disc-jet system as a whole undergoes Lense-Thirring precession and approaches alignment, demonstrating for the first time that jets can be used as probes of disc precession. When the disc turbulence is well-resolved, our isolated discs spread out, causing both the alignment and precession to slow down.
M. Liska, C. Hesp, A. Tchekhovskoy, et. al.
Fri, 21 Jul 17
46/59
Comments: Submitted to MNRAS Letters, comments welcome. 5 pages, 4 figures. Animations available at this https URL