Spiral Structure in the Gas Disk of TW Hya

TL;DR

This study detects spiral structures in the gas velocity and temperature of TW Hya's disk, indicating possible planet-disk interactions and revealing tightly wound spirals with decreasing pitch angles.

Contribution

First observation of gas velocity and temperature spirals in TW Hya's disk, suggesting complex planet-disk interaction mechanisms beyond simple wake models.

Findings

Spiral perturbations in gas velocity and temperature detected.

Pitch angles of spirals decrease from 9° to 3° with radius.

Tightly wound spirals imply alternative launching mechanisms.

Abstract

We report the detection of spiral substructure in both the gas velocity and temperature structure of the disk around TW~Hya, suggestive of planet-disk interactions with an unseen planet. Perturbations from Keplerian rotation tracing out a spiral pattern are observed in the SE of the disk, while significant azimuthal perturbations in the gas temperature are seen in the outer disk, outside 90~au, extending the full azimuth of the disk. The deviation in velocity is either $\Delta v_{\phi} \, / \, v_{\rm kep} \sim 0.1$ or $\Delta v_{z} \, / \, v_{\rm kep} \sim 0.01$ depending on whether the perturbation is in the rotational or vertical direction, while radial perturbations can be ruled out. Deviations in the gas temperature are $\pm 4$ K about the azimuthally averaged profile, equivalent to deviations of $\Delta T_{\rm gas} \, / \, T_{\rm gas} \sim 0.05$. Assuming all three structures can be described by an Archimedean spiral, measurements of the pitch angles of both velocity and temperature spirals show a radially decreasing trend for all three, ranging from 9$^{\circ}$ at 70 au, dropping to 3$^{\circ}$ at 200 au. Such low pitch-angled spirals are not readily explained through the wake of an embedded planet in the location of previously reported at 94 au, but rather require a launching mechanism which results in much more tightly wound spirals. Molecular emission tracing distinct heights in the disk is required to accurately distinguish between spiral launching mechanisms.