Substructures in protoplanetary disks imprinted by compact planetary systems

TL;DR

This study explores how compact systems of Neptune-like planets can create long-lived vortices in protoplanetary disks, offering explanations for observed disk substructures and challenging previous assumptions about planet mass inference.

Contribution

It demonstrates that multiple Neptune-mass planets can produce persistent vortices in disks, especially when closely spaced, revealing new insights into disk-planet interactions and substructure formation.

Findings

Long-lived vortices occur when planetary separation is less than 8 disk scale heights.

Two-planet systems can sustain vortices for over 5,000 orbits.

Vortices can form in shared or partially-shared gaps, influenced by planet spacing and resonances.

Abstract

The substructures observed in protoplanetary disks may be the signposts of embedded planets carving gaps or creating vortices. The inferred masses of these planets often fall in the Jovian regime despite their low abundance compared to lower-mass planets, partly because previous works often assume that a single substructure (a gap or vortex) is caused by a single planet. In this work, we study the possible imprints of compact systems composed of Neptune-like planets ($\sim10-30\;M_\oplus$) and show that long-standing vortices are a prevalent outcome when their inter-planetary separation ($\Delta a$) falls below $\sim8$ times $H_{{\rm p}}$ -- the average disk's scale height at the planets locations. In simulations where a single planet is unable to produce long-lived vortices, two-planet systems can preserve them for at least $5,000$ orbits in two regimes: i) fully-shared density gaps with elongated vortices around the stable Lagrange points $L_4$ and $L_5$ for the most compact planet pairs ($\Delta a \lesssim 4.6\; H_{{\rm p}}$); ii) partially-shared gaps for more widely spaced planets ($\Delta a \sim 4.6 - 8\;H_{{\rm p}}$) forming vortices in a density ring between the planets through the Rossby wave instability. The latter case can produce vortices with a wide range of aspect ratios down to $\sim3$ and can occur for planets captured into the 3:2 (2:1) mean-motion resonances for disk's aspects ratios of $h\gtrsim 0.033$ ($h\gtrsim 0.057$). We suggest that their long lifetimes are sustained by the interaction of spiral density waves launched by the neighboring planets. Overall, our results show that distinguishing imprint of compact systems with Neptune-mass planets are long-lived vortices inside the density gaps, which in turn are shallower than single-planet gaps for a fixed gap width.