Saturation of the magnetorotational instability and the origin of magnetically elevated accretion discs

TL;DR

This paper presents a self-regulation mechanism for MRI-driven turbulence in accretion discs, explaining the scaling of angular momentum transport and exploring conditions for magnetically elevated discs.

Contribution

It introduces a self-regulation model for MRI turbulence that reproduces known alpha-parameter scaling and extends the analysis to strongly magnetized discs with potential turbulence sources.

Findings

MRI growth saturates due to turbulent resistivity damping the fastest mode.

The alpha-parameter scales as $eta_z^{-1/2}$, consistent with previous simulations.

Additional turbulence mechanisms, like tearing modes, may be needed for magnetically elevated discs.

Abstract

We propose that the strength of angular momentum transport in accretion discs threaded by net vertical magnetic field is determined by a self-regulation mechanism: the magnetorotational instability (MRI) grows until its own turbulent resistivity damps the fastest growing mode on the scale of the disc thickness. Given weak assumptions as to the structure of MRI-derived turbulence, supported by prior simulation evidence, the proposed mechanism reproduces the known scaling of the viscous $\alpha$-parameter, $\alpha \propto \beta_z^{-1/2}$. Here, $\beta_z = 8\pi p_g/B_{z0}^2$ is the initial plasma $\beta$-parameter on the disc midplane, $B_{z0}$ is the net field, and $p_g $ is the midplane gas pressure. We generalize the argument to discs with strong suprathermal toroidal magnetic fields, where the MRI growth rate is modified from the weak-field limit. Additional sources of turbulence are required if such discs are to become magnetically elevated, with the increased scale heights near the midplane that are seen in simulations. We speculate that tearing modes, associated with current sheets broadened by the effective resistivity, are a possible source of enhanced turbulence in elevated discs.