LBT search for companions and sub-structures in the (pre)transitional disk of AB Aurigae

TL;DR

This study uses high-resolution multi-wavelength imaging to search for companions and sub-structures in AB Aurigae's protoplanetary disk, setting new detection limits and revealing disk features that inform planet formation processes.

Contribution

The paper provides new deep L' and Ks band images of AB Aurigae, establishing improved detection limits for planetary companions and revealing disk structures at L'-band for the first time.

Findings

No planetary companions detected within the sensitivity limits.

Inner spiral structures and a ring with asymmetry are observed.

Dust trapping mechanisms are suggested by the disk features.

Abstract

Multi-wavelengths high-resolution imaging of protoplanetary disks has revealed the presence of multiple, varied substructures in their dust and gas components which might be signposts of young, forming planetary systems. AB Aurigae bears an emblematic (pre)transitional disk showing spiral structures observed in the inner cavity of the disk in both the sub-millimeter (ALMA; 1.3mm, $^{12}$CO) and near-infrared (SPHERE; 1.5-2.5$\mu$m) wavelengths which have been claimed to arise from dynamical interactions with a massive companion. In this work, we present new deep $K_s$ (2.16$\mu$m) and L' (3.7$\mu$m) band images of AB Aurigae obtained with LMIRCam on the Large Binocular Telescope, aimed for the detection of both planetary companions and extended disk structures. No point source is recovered, in particular at the outer regions of the disk, where a putative candidate ($\rho = 0.681", PA = 7.6^{\circ}$) had been previously claimed. The nature of a second innermost planet candidate ($\rho = 0.16'', PA = 203.9^{\circ}$) can not be investigated by the new data. We are able to derive 5$\sigma$ detection limits in both magnitude and mass for the system, going from 14 \Mjup at 0.3'' (49 au) down to 3-4 \Mjup at 0.6'' (98 au) and beyond, based on the ATMO 2020 evolutionary models. We detect the inner spiral structures (< 0.5'') resolved in both CO and polarimetric H-band observations. We also recover the ring structure of the system at larger separation (0.5-0.7") showing a clear south-east/north-west asymmetry. This structure, observed for the first time at L'-band, remains interior to the dust cavity seen at ALMA, suggesting an efficient dust trapping mechanism at play in the disk.