CO and H2 Absorption in the AA Tauri Circumstellar Disk

TL;DR

This study uses far-ultraviolet spectroscopy with HST to measure molecular gas properties in the inner disk of AA Tauri, revealing high-temperature CO and H2 gas likely in an inner disk atmosphere.

Contribution

First direct measurement of CO and H2 absorption in the inner protoplanetary disk of AA Tauri using HST UV spectroscopy, providing new insights into molecular gas conditions.

Findings

CO column density ~3.2 x 10^{17} cm^{-2} with T_rot ~500 K

H2 column density ~8 x 10^{17} cm^{-2} with T ~2500 K

Evidence of non-thermal H2 excitation processes

Abstract

The direct study of molecular gas in inner protoplanetary disks is complicated by uncertainties in the spatial distribution of the gas, the time-variability of the source, and the comparison of observations across a wide range of wavelengths. Some of these challenges can be mitigated with far-ultraviolet spectroscopy. Using new observations obtained with the HST-Cosmic Origins Spectrograph, we measure column densities and rovibrational temperatures for CO and H2 observed on the line-of-sight through the AA Tauri circumstellar disk. CO A-X absorption bands are observed against the far-UV continuum. The CO absorption is characterized by log(N(^{12}CO)) = 17.5 +/- 0.5 cm^{-2} and T_rot(CO) = 500$^{+500}_{-200} K, although this rotational temperature may underestimate the local kinetic temperature of the CO-bearing gas. We also detect ^{13}CO in absorption with an isotopic ratio of ~20. We do not observe H2 absorption against the continuum; however, hot H2 (v > 0) is detected in absorption against the LyA emission line. We measure the column densities in eight individual rovibrational states, determining a total log(N(H2)) = 17.9^{+0.6}_{-0.3} cm^{-2} with a thermal temperature of T(H2) = 2500^{+800}_{-700} K. The high-temperature of the molecules, the relatively small H2 column density, and the high-inclination of the AA Tauri disk suggest that the absorbing gas resides in an inner disk atmosphere. If the H2 and CO are co-spatial within a molecular layer ~ 0.6 AU thick, this region is characterized by <n_H2> ~ 10^{5} cm^{-3} with an observed <CO/H2> ratio of ~ 0.4. We also find evidence for a departure from a purely thermal H2 distribution, suggesting that excitation by continuum photons and H2 formation may be altering the level populations in the molecular gas.