The Irradiation Instability of Protoplanetary Disks

TL;DR

This paper investigates the irradiation instability in protoplanetary disks, revealing how geometric changes in the disk's structure can lead to thermal waves, potentially explaining observed rings and gaps.

Contribution

The study provides an analytical and numerical analysis of the irradiation instability, demonstrating its mechanism and potential impact on disk morphology and planet formation.

Findings

Instability causes thermal waves with order-unity amplitude.

Disk appearance may show bright rings and dark gaps.

Could explain observed ALMA rings and gaps.

Abstract

The temperature in most parts of a protoplanetary disk is determined by irradiation from the central star. Numerical experiments of Watanabe \& Lin (2008) suggested that such disks, also called `passive disks', suffer from a thermal instability. Here, we use analytical and numerical tools to elucidate the nature of this instability. We find that it is related to the flaring of the optical surface, the layer at which starlight is intercepted by the disk. Whenever a disk annulus is perturbed thermally and acquires a larger scale height, disk flaring becomes steeper in the inner part, and flatter in the outer part. Starlight now shines more overhead for the inner part and so can penetrate into deeper layers; conversely, it is absorbed more shallowly in the outer part. These geometric changes allow the annulus to intercept more starlight, and the perturbation grows. We call this the irradiation instability. It requires only ingredients that are known to exist in realistic disks, and operates best in parts that are both optically thick and geometrically thin (inside 30AU, but can extend to further reaches when, e.g., dust settling is considered). An unstable disk develops travelling thermal waves that reach order-unity in amplitude. In thermal radiation, such a disk should appear as a series of bright rings interleaved with dark shadowed gaps, while in scattered light it resembles a moving staircase. Depending on the gas and dust responses, this instability could lead to a wide range of consequences, such as {\w ALMA rings and gaps,} dust traps, vertical circulation, vortices and turbulence.