A symmetric inner cavity in the HD 141569A transitional disk

TL;DR

This study uses advanced imaging techniques to analyze the complex structure of the HD 141569A transitional disk, revealing an almost axisymmetric inner edge, substructures, and potential multiple belts, providing insights into planet formation processes.

Contribution

The paper provides a detailed re-analysis of high-resolution images of HD 141569A, revealing new disk structures and clarifying the nature of the arc at 250 AU, with implications for understanding disk evolution.

Findings

Inner disk is nearly axisymmetric.

Eastern side is wider and more complex.

Arc at 250 AU may be a separate belt.

Abstract

Some circumstellar disks, called transitional or hybrid disks, present characteristics of both protoplanetary disks (significant amount of gas) and debris disks (evolved structures around young main-sequence stars, composed of second generation dust, from collisions between planetesimals). Therefore, they are an ideal astrophysical laboratory to witness the last stages of planet formation. The circumstellar disk around HD~141569A was intensively observed and resolved in the past from space but also from the ground but the recent implementation of high contrast imaging systems opens new opportunities to re-analyze this object. We analyzed Gemini archival data from the Near-Infrared Coronagraphic Imager (NICI) obtained in 2011 in the H band, using several angular differential imaging techniques (classical ADI, LOCI, KLIP). These images reveal the complex structures of this disk with an unprecedented resolution. We also include archival Hubble Space Telescope (HST) images as an independent dataset to confirm these findings. Using an analysis of the inner edge of the disk, we show that the inner disk is almost axisymmetrical. The measurement of an offset towards the East observed by previous authors is likely due to the fact that the Eastern part of this disk is wider and more complex in substructure. Our precise re-analysis of the eastern side shows several structures including a splitting of the disk and a small finger detached from the inner edge on the southeast. Finally, we find that the arc at 250 AU is unlikely to be a spiral, at least not at the inclination derived from the first ring, but instead could be interpreted as a third belt at a different inclination. If the very symmetrical inner disk edge is carved by a companion, the data presented here put additional constraints on its position.