Spiral formation caused by late infall onto protoplanetary disks

TL;DR

This study investigates how late infall of material onto protoplanetary disks can generate spiral structures, affecting disk dynamics and potentially influencing planet formation, using hydrodynamic simulations and radiative transfer analysis.

Contribution

It demonstrates that late infall can produce observable spiral patterns in disks, with specific characteristics depending on accretion mode and disk properties, advancing understanding of disk-environment interactions.

Findings

Well-defined m=2 spirals can form from late infall, with low pattern speeds.

Active accretion via streamers leads to more flocculent spiral structures.

Disk perturbations are strongest in upper layers, affecting residual motions in CO emissions.

Abstract

The classical picture that planet formation occurs in protoplanetary disks that are isolated from their environment is undergoing a major shift toward a more connected picture. An increasing amount of evolved disks are found to be actively interacting with their environment, often showing various types of spiral structures. In this work, we aim to investigate if these spirals can be a direct result of ongoing late infall using the grid-based 3D hydrodynamics code FARGO3D. We perform a detailed analysis of the spiral properties and appearance in scattered light and CO line emission using the radiative transfer code RADMC3D. In scattered light, we find both well-defined spirals with few arms (m=2) and more flocculent structures: The gradual accretion of gas remnants after a major accretion event has the most success in the former, whereas active accretion via streamers favors the latter. The m=2 spirals we find have a very low pattern speed, making them easily discernible from spirals caused by a perturber. We also find spiral patterns in the $^{12}$CO residual motions, but their morphology does not match the one found in scattered light. The disk perturbations are strongest in the upper layers (z>4H), which is reflected by the reduced amplitude of the residual motions in the more optically thin $^{13}$CO emission. Moreover, we find that the formation of m=2 spirals is not promoted in disks with lower mass, despite being more susceptible to deeper kinematic perturbations. While the late-infall streamers impact planet formation directly through the delivery of fresh material, we show that the midplane remains unperturbed unless the infalling mass is of the same order of magnitude as the disk mass. Planet formation can therefore only be impacted by late infall through secondary mechanisms that lead to dust trapping or the generation of turbulence starting from surface-level perturbations.