Studies of Thermally Unstable Accretion Disks around Black Holes with Adaptive Pseudospectral Domain Decomposition Method. II. Limit-Cycle Behavior in accretion disks around Kerr black holes

TL;DR

This paper derives relativistic equations for slim accretion disks around Kerr black holes, models their non-stationary behavior, and explores limit-cycle phenomena influenced by parameters like mass supply and viscosity, with implications for observed microquasar variability.

Contribution

It introduces a numerical method for modeling time-evolving relativistic accretion disks with various viscosity prescriptions, including the standard alpha model and recent MHD-inspired models.

Findings

Limit-cycle properties depend mainly on mass-supply rate and alpha-viscosity.

Maximum outburst luminosity correlates with black hole spin.

Cycle duration shows no clear dependence on black hole spin.

Abstract

For the first time ever, we derive equations governing the time-evolution of fully relativistic slim accretion disks in the Kerr metric, and numerically construct their detailed non-stationary models. We discuss applications of these general results to a possible limit-cycle behavior of thermally unstable disks. Our equations and numerical method are applicable in a wide class of possible viscosity prescriptions, but in this paper we use a diffusive form of the "standard alpha prescription" that assumes the viscous torque is proportional to the total pressure. In this particular case, we find that the parameters which dominate the limit-cycle properties are the mass-supply rate and the value of the alpha-viscosity parameter. Although the duration of the cycle (or the outburst) does not exhibit any clear dependence on the black hole spin, the maximal outburst luminosity (in the Eddington units) is positively correlated with the spin value. We suggest a simple method for a rough estimate of the black hole spin based on the maximal luminosity and the ratio of outburst to cycle durations. We also discuss a temperature-luminosity relation for the Kerr black hole accretion discs limit-cycle. Based on these results we discuss the limit-cycle behavior observed in microquasar GRS 1915+105. We also extend this study to several non-standard viscosity prescriptions, including a "delayed heating" prescription recently stimulated by the recent MHD simulations of accretion disks.