GRRMHD Simulations of MAD Accretion Disks Declining from Super-Eddington to Sub-Eddington Accretion Rates

Abstract

We present two general relativistic radiation magnetohydrodynamics (GRRMHD) simulations of magnetically arrested disks (MADs) around non-spinning (a*=0) and spinning (a*=0.9) supermassive black holes (BHs). In each simulation, the mass accretion rate is decreased with time such that we sample Eddington-scaled rates over the range 3 M/MEdd 0.3. For the non-spinning BH model, the total and radiative efficiencies increase as the accretion rate decreases, varying over the range ηtot9-16\% and ηrad6-12\%, respectively. This model shows very little jet activity. In contrast, the spinning BH model has a strong relativistic jet powered by spin energy extracted from the BH. The jet power declines with accretion rate such that ηjet 18-39\% while the total and radiative efficiencies are ηtot 64-100\% and ηrad 45-79\%, respectively. We confirm that mildly sub-Eddington disks can extract substantial power from a spinning BH, provided they are in the MAD state. The jet profile out to 100\, GM/c2 is roughly parabolic with a power-law index of k≈0.43-0.53 during the sub-Eddington evolution. Both models show significant variability in the outgoing radiation which is likely associated with episodes of magnetic flux eruptions. The a*=0.9 model shows semi-regular variations with a period of 2000\, GM/c3 over the final 10,000\, GM/c3 of the simulation, which suggests that magnetic flux eruptions may be an important source of quasi-periodic variability. For the simulated accretion rates, the a*=0 model is spinning up while the a*=0.9 model is spinning down. Spinup-spindown equilibrium of the BH will likely be achieved at 0.5 < a*,eq < 0.6, assuming continuous accretion in the MAD state.