English

Mapping the Complex Kinematic Substructure in the TW Hya Disk

Earth and Planetary Astrophysics 2022-09-21 v1 Solar and Stellar Astrophysics

Abstract

We present ALMA observations of CO J=21J = 2-1 and CS J=54J = 5-4 emission from the disk around TW~Hydrae. Both molecules trace a predominantly Keplerian velocity structure, although a slowing of the rotation velocity is detected at the outer edge of the disk beyond  140{\approx}~140~au in CO emission. This was attributed to the enhanced pressure support from the gas density taper near the outer edge of the disk. Subtraction of an azimuthally symmetric background velocity structure reveals localized deviations in the gas kinematics traced by each of the molecules. Both CO and CS exhibit a `Doppler flip' feature, centered nearly along the minor axis of the disk (PA60\degr{\rm PA} \sim 60\degr) at a radius of 1\farcs351\farcs35, coinciding with the large gap observed in scattered light and mm~continuum. In addition, the CO emission, both through changes in intensity and its kinematics, traces a tightly wound spiral, previously seen with higher frequency CO J=32J = 3-2 observations (Teague et al., 2019). Through comparison with linear models of the spiral wakes generated by embedded planets, we interpret these features in the context of interactions with a Saturn-mass planet within the gap at a position angle of PA=60\degr{\rm PA} = 60\degr, consistent with the theoretical predictions of (Mentiplay et al. 2019). The lack of a corresponding spiral in the CS emission is attributed to the strong vertical dependence on the buoyancy spirals which are believed to only grow in the atmospheric of the disk, rather than those traced by CS emission.

Keywords

Cite

@article{arxiv.2208.04837,
  title  = {Mapping the Complex Kinematic Substructure in the TW Hya Disk},
  author = {Richard Teague and Jaehan Bae and Sean M. Andrews and Myriam Benisty and Edwin A. Bergin and Stefano Facchini and Jane Huang and Cristiano Longarini and David Wilner},
  journal= {arXiv preprint arXiv:2208.04837},
  year   = {2022}
}

Comments

Accepted to ApJ

R2 v1 2026-06-25T01:36:03.309Z