Astronomy and Astrophysics, volume 516, A110-110 (2010/6-3)
Where is the warm H2? A search for H2 emission from disks around Herbig Ae/Be stars.
MARTIN-ZAIEDI C., AUGEREAU J.-C., MENARD F., OLOFSSON J., CARMONA A., PINTE C. and HABART E.
Abstract (from CDS):
Mid-infrared (mid-IR) emission lines of molecular hydrogen (H2) are useful probes to determine the mass of warm gas present in the surface layers of circumstellar disks. In the past years, numerous observations of Herbig Ae/Be stars (HAeBes) have been performed, but only two detections of H2 mid-IR emission toward HD 97048 and AB Aur have been reported. We aim at tracing the warm gas in the circumstellar environment of five additional HAeBes with gas-rich environments and/or physical characteristics close to those of AB Aur and/or HD 97048, to discuss whether the detections toward these two objects are suggestive of peculiar conditions for the observed gas. We search for the H2 S(1) emission line at 17.035µm using high-resolution mid-IR spectra obtained with VLT/VISIR, and complemented by CH molecule observations with VLT/UVES. We gather the H2 measurements from the literature to put the new results in context and search for a correlation with some disk properties. None of the five VISIR targets shows evidence for H2 emission at 17.035µm. From the 3σ upper limits on the integrated line fluxes we constrain the amount of optically thin warm (>150K) gas to be less than ∼1.4MJup in the disk surface layers. There are now 20 HAeBes observed with VISIR and TEXES instruments to search for warm H2, but only two detections (HD 97048 and AB Aur) were made so far. We find that the two stars with detected warm H2 show at the same time high 30/13µm flux ratios and large PAH line fluxes at 8.6 and 11.3µm compared to the bulk of observed HAeBes and have emission CO lines detected at 4.7µm. We detect the CH 4300.3Å absorption line toward both HD 97048 and AB Aur with UVES. The CH to H2 abundance ratios that this would imply if it were to arise from the same component as well as the radial velocity of the CH lines both suggest that CH arises from a surrounding envelope, while the detected H2 would reside in the disk. The two detections of the S(1) line in the disks of HD 97048 and AB Aur suggest either peculiar physical conditions or a particular stage of evolution. New instruments such as Herschel/ PACS should bring significant new data for the constraints of thermodynamics in young disks by observing the gas and the dust simultaneously.