Rapid, strongly magnetized accretion in the zero-net-vertical-flux shearing box

TL;DR

This paper identifies a new strongly magnetized turbulent state in zero-net-flux shearing box simulations, which exhibits high accretion stress and may explain observed state transitions in accretion disks.

Contribution

It introduces the low-$eta$ state characterized by strong magnetization and high turbulence, expanding understanding of accretion disk turbulence regimes.

Findings

The low-$eta$ state has $eta o 1$ and high $ ext{alpha} o 1$.

The low-$eta$ state is sustained by a dynamo mechanism involving differential rotation and Parker instability.

Vertical force balance is dominated by magnetic pressure in the low-$eta$ state.

Abstract

We show that there exist two qualitatively distinct turbulent states of the zero-net-vertical-flux shearing box. The first, which has been studied in detail previously, is characterized by a weakly magnetized ($\beta\sim50$) midplane with slow periodic reversals of the mean azimuthal field (dynamo cycles). The second, the 'low-$\beta$ state,' which is the main subject of this paper, is characterized by a strongly magnetized $\beta\sim 1$ midplane dominated by a coherent azimuthal field with much stronger turbulence and much larger accretion stress ($\alpha \sim 1$). The low-$\beta$ state emerges in simulations initialized with sufficiently strong azimuthal magnetic fields. The mean azimuthal field in the low-$\beta$ state is quasi steady (no cycles) and is sustained by a dynamo mechanism that compensates for the continued loss of magnetic flux through the vertical boundaries; we attribute the dynamo to the combination of differential rotation and the Parker instability, although many of its details remain unclear. Vertical force balance in the low-$\beta$ state is dominated by the mean magnetic pressure except at the midplane, where thermal pressure support is always important (this holds true even when simulations are initialized at $\beta \ll 1$, provided the thermal scale height of the disk is well resolved). The efficient angular momentum transport in the low-$\beta$ state may resolve long-standing tension between predictions of magnetorotational turbulence (at high $\beta$) and observations; likewise, the bifurcation in accretion states we identify may be important for understanding the state transitions observed in dwarf novae, X-ray binaries, and changing-look AGN. We discuss directions for future work, including the implications of our results for global accretion disk models and simulations.