Global simulations of protoplanetary disks with net magnetic flux: I. Non-ideal MHD case

TL;DR

This study presents the first global simulations of weakly ionized protoplanetary disks with large-scale magnetized winds, revealing how magnetic field configurations influence accretion, wind formation, and disk self-organization into rings.

Contribution

It introduces comprehensive 3D stratified MHD simulations including all non-ideal effects, demonstrating the conditions for wind-driven accretion and disk self-organization in protoplanetary disks.

Findings

Magnetized winds can drive accretion depending on magnetic field configuration.

Disks exhibit asymmetric winds and mass loss rates linked to magnetic pressure.

Self-organization leads to axisymmetric rings and pressure bumps.

Abstract

The planet-forming region of protoplanetary disks is cold, dense, and therefore weakly ionized. For this reason, magnetohydrodynamic (MHD) turbulence is thought to be mostly absent, and another mechanism has to be found to explain gas accretion. It has been proposed that magnetized winds, launched from the ionized disk surface, could drive accretion in the presence of a large-scale magnetic field. The efficiency and the impact of these surface winds on the disk structure is still highly uncertain. We present the first global simulations of a weakly ionized disk that exhibits large-scale magnetized winds. We also study the impact of self-organization, which was previously demonstrated only in non-stratified models. We perform numerical simulations of stratified disks with the PLUTO code. We compute the ionization fraction dynamically, and account for all three non-ideal MHD effects: ohmic and ambipolar diffusions, and the Hall drift. Simplified heating and cooling due to non-thermal radiation is also taken into account in the disk atmosphere. We find that disks can be accreting or not, depending on the configuration of the large-scale magnetic field. Magnetothermal winds, driven both by magnetic acceleration and heating of the atmosphere, are obtained in the accreting case. In some cases, these winds are asymmetric, ejecting predominantly on one side of the disk. The wind mass loss rate depends primarily on the average ratio of magnetic to thermal pressure in the disk midplane. The non-accreting case is characterized by a meridional circulation, with accretion layers at the disk surface and decretion in the midplane. Finally, we observe self-organization, resulting in axisymmetric rings of density and associated pressure "bumps". The underlying mechanism and its impact on observable structures are discussed.