Magnetic disk winds in protoplanetary disks: Description of the model and impact on global disk evolution

TL;DR

This paper develops a comprehensive global model of magnetic disk winds in protoplanetary disks, demonstrating their significant role in disk evolution and aligning well with observational data from ALMA surveys.

Contribution

It introduces a self-consistent, parameter-constrained magnetic wind model integrated into disk evolution simulations, incorporating dust, self-gravity, and adaptive turbulence.

Findings

Models with disk winds match observational data.

Magnetic winds significantly influence disk evolution.

Synthetic observations agree with ALMA survey results.

Abstract

Canonically, a protoplanetary disk is thought to undergo (gravito-)viscous evolution, wherein the angular momentum of the accreting material is transported outwards. However, several lines of reasoning suggest that the turbulent viscosity in a typical protoplanetary disk is insufficient to drive the observed accretion rates. An emerging paradigm suggests that radially extended magnetic disk winds may play a crucial role in the disk evolution. We propose a global model of magnetic wind-driven accretion for evolution of protoplanetary disks, based on the insights gained from local shearing box simulations. Here we develop this model and constrain its parameters with the help of theoretical expectations and comparison with observations. The magnetic wind is characterized with the associated loss of angular momentum and mass, which depend on the local disk conditions and stellar properties. We incorporate the disk winds self-consistently in the code FEOSAD and study formation and long-term evolution of protoplanetary disks. We include disk self-gravity and an adaptive turbulent alpha, while the co-evolution of dust is also considered. Synthetic observations are obtained via radiation thermo-chemical code ProDiMo. The models with inclusion of disk winds satisfy general expectations from both theory and observations. The disk wind parameters can be guided by observational constraints and the synthetic observations resulting from such a model compare favorably with the selected ALMA survey data of Class II disks. The proposed magnetic disk wind model is a significant step forward in the direction of representing a more complete disk evolution, wherein the disk experiences concurrent torques from viscous, gravitational, and magnetic wind processes.