Efficiency of Thin Magnetically-Arrested Disks Around Black Holes

Abstract

The radiative and jet efficiencies of thin magnetized accretion disks around black holes (BHs) are affected by BH spin and the presence of a magnetic field that, when strong, could lead to large deviations from Novikov-Thorne (NT) thin disk theory. To seek the maximum deviations, we perform general relativistic magnetohydrodynamic (GRMHD) simulations of radiatively efficient thin (half-height H to radius R of H/R≈ 0.10) disks around moderately rotating BHs with a/M=0.5. First, our simulations, each evolved for more than 70,000rg/c (gravitational radius rg and speed of light c), show that large-scale magnetic field readily accretes inward even through our thin disk and builds-up to the magnetically-arrested disk (MAD) state. Second, our simulations of thin MADs show the disk achieves a radiative efficiency of η r≈ 15\% (after estimating photon capture), which is about twice the NT value of η r 8\% for a/M=0.5 and gives the same luminosity as a NT disk with a/M≈ 0.9. Compared to prior simulations with 10\% deviations, our result of an ≈ 80\% deviation sets a new benchmark. Building on prior work, we are now able to complete an important scaling law which suggest that observed jet quenching in the high-soft state in BH X-ray binaries is consistent with an ever-present MAD state with a weak yet sustained jet.