# New constraints on the disk characteristics and companion candidates   around T Cha with VLT/SPHERE

**Authors:** A. Pohl, E. Sissa, M. Langlois, A. M\"uller, C. Ginski, R. G. van, Holstein, A. Vigan, D. Mesa, A.-L. Maire, Th. Henning, R. Gratton, J., Olofsson, R. van Boekel, M. Benisty, B. Biller, A. Boccaletti, G. Chauvin, S., Daemgen, J. de Boer, S. Desidera, C. Dominik, A. Garufi, M. Janson, Q. Kral,, F. M\'enard, C. Pinte, T. Stolker, J. Szul\'agyi, A. Zurlo, M. Bonnefoy, A., Cheetham, M. Cudel, M. Feldt, M. Kasper, A.-M. Lagrange, C. Perrot, F., Wildi

arXiv: 1705.03477 · 2017-09-06

## TL;DR

This study uses high-resolution VLT/SPHERE imaging to analyze the disk structure and search for companions around T Cha, revealing a highly inclined disk with a gap, dust grain properties, and constraining potential companion masses.

## Contribution

First detailed high-resolution imaging and modeling of T Cha's disk, including constraints on dust grain sizes, disk geometry, and limits on companion masses.

## Key findings

- Outer disk resolved in scattered light with high resolution
- Disk inclination ~69 degrees, PA ~114 degrees
- Companion mass limit ~8.5 Jupiter masses between 0.1" and 0.3"

## Abstract

The transition disk around the T Tauri star T Cha possesses a large gap, making it a prime target for high-resolution imaging in the context of planet formation. We aim to find signs of disk evolutionary processes by studying the disk geometry and the dust grain properties at its surface, and to search for companion candidates. We analyze a set of VLT/SPHERE data at near-infrared and optical wavelengths. We performed polarimetric imaging of T Cha with IRDIS (1.6 $\mu$m) and ZIMPOL (0.5-0.9 $\mu$m), and obtained intensity images from IRDIS dual-band imaging with simultaneous spectro-imaging with IFS (0.9-1.3 $\mu$m). The disk around T Cha is detected in all observing modes and its outer disk is resolved in scattered light with unprecedented angular resolution and signal-to-noise. The images reveal a highly inclined disk with a noticeable east-west brightness asymmetry. The significant amount of non-azimuthal polarization signal in the $U_{\phi}$ images, with a $U_{\phi}$/$Q_{\phi}$ peak-to-peak value of 14%, is in accordance with theoretical studies on multiple scattering. Our optimal axisymmetric radiative transfer model considers two coplanar inner and outer disks, separated by a gap of 0.28" (~30au) in size. We derive a disk inclination of ~69 deg and PA of ~114 deg. In order to self-consistently reproduce the intensity and polarimetric images, the dust grains, responsible for the scattered light, need to be dominated by sizes of around ten microns. A point source is detected at an angular distance of 3.5" from the central star. It is, however, found not to be co-moving. We confirm that the dominant source of emission is forward scattered light from the near edge of the outer disk. Our point source analysis rules out the presence of a companion heavier than ~8.5 $M_{\mathrm{jup}}$ between 0.1" and 0.3". The detection limit decreases to ~2 $M_{\mathrm{jup}}$ for 0.3" to 4.0".

## Full text

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## Figures

18 figures with captions in the complete paper: https://tomesphere.com/paper/1705.03477/full.md

## References

90 references — full list in the complete paper: https://tomesphere.com/paper/1705.03477/full.md

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Source: https://tomesphere.com/paper/1705.03477