Direct calculation of the radiative efficiency of an accretion disk around a black hole

TL;DR

This paper extends a general relativistic MHD code to 3D, enabling direct calculation of radiative efficiency in accretion disks around black holes, revealing significant dissipation and luminosity beyond classical models.

Contribution

It introduces a 3D relativistic MHD simulation with explicit radiative cooling and ray-tracing to directly compute accretion disk luminosity, improving upon previous models.

Findings

Significant dissipation occurs beyond classical predictions.

Net luminosity exceeds Novikov-Thorne estimates by 6%.

Total potential luminosity could be 20% higher if all thermal energy is radiated.

Abstract

Numerical simulation of magnetohydrodynamic (MHD) turbulence makes it possible to study accretion dynamics in detail. However, special effort is required to connect inflow dynamics (dependent largely on angular momentum transport) to radiation (dependent largely on thermodynamics and photon diffusion). To this end we extend the flux-conservative, general relativistic MHD code HARM from axisymmetry to full 3D. The use of an energy conserving algorithm allows the energy dissipated in the course of relativistic accretion to be captured as heat. The inclusion of a simple optically thin cooling function permits explicit control of the simulated disk's geometric thickness as well as a direct calculation of both the amplitude and location of the radiative cooling associated with the accretion stresses. Fully relativistic ray-tracing is used to compute the luminosity received by distant observers. For a disk with aspect ratio H/r ~ 0.1 accreting onto a black hole with spin parameter a/M = 0.9, we find that there is significant dissipation beyond that predicted by the classical Novikov-Thorne model. However, much of it occurs deep in the potential, where photon capture and gravitational redshifting can strongly limit the net photon energy escaping to infinity. In addition, with these parameters and this radiation model, significant thermal and magnetic energy remains with the gas and is accreted by the black hole. In our model, the net luminosi ty reaching infinity is 6% greater than the Novikov-Thorne prediction. If the accreted thermal energy were wholly radiated, the total luminosity of the accretion flow would be ~20% greater than the Novikov-Thorne value.