English

Gas temperature structure across transition disk cavities

Earth and Planetary Astrophysics 2022-07-06 v1 Astrophysics of Galaxies Solar and Stellar Astrophysics

Abstract

[Abridged] Most disks observed at high angular resolution show substructures. Knowledge about the gas surface density and temperature is essential to understand these. The aim of this work is to constrain the gas temperature and surface density in two transition disks: LkCa15 and HD 169142. We use new ALMA observations of the 13^{13}CO J=65J=6-5 transition together with archival J=21J=2-1 data of 12^{12}CO, 13^{13}CO and C18^{18}O to observationally constrain the gas temperature and surface density. Furthermore, we use the thermochemical code DALI to model the temperature and density structure of a typical transition disk. The 65/216-5/2-1 line ratio in LkCa15 constrains the gas temperature in the emitting layers inside the dust cavity to be up to 65 K, warmer than in the outer disk at 20-30 K. For the HD 169142, the peak brightness temperature constrains the gas in the dust cavity of HD 169142 to be 170 K, whereas that in the outer disk is only 100 K. Models also show that a more luminous central star, a lower abundance of PAHs and the absence of a dusty inner disk increase the temperature of the emitting layers and hence the line ratio in the gas cavity. The gas column density in the LkCa15 dust cavity drops by a factor >2 compared to the outer disk, with an additional drop of an order of magnitude inside the gas cavity at 10 AU. In the case of HD 169142, the gas column density drops by a factor of 200-500 inside the gas cavity, which could be due to a massive companion of several MJ_{\mathrm{J}}. The broad dust-depleted gas region from 10-68 AU for LkCa15 may imply several lower mass planets. This work demonstrates that knowledge of the gas temperature is important to determine the gas surface density and thus whether planets, and if so what kind of planets, are the most likely carving the dust cavities.

Keywords

Cite

@article{arxiv.2204.03666,
  title  = {Gas temperature structure across transition disk cavities},
  author = {M. Leemker and A. S. Booth and E. F. van Dishoeck and A. F. Pérez-Sánchez and J. Szulágyi and A. D. Bosman and S. Bruderer and S. Facchini and M. R. Hogerheijde and T. Paneque-Carreño and J. A. Sturm},
  journal= {arXiv preprint arXiv:2204.03666},
  year   = {2022}
}

Comments

Accepted for publication in Astronomy and astrophysics

R2 v1 2026-06-24T10:41:38.370Z