Abstract
Context. A crucial issue in star formation is understanding the physical mechanism by which mass is accreted onto and ejected by a young star, then collimated into jets. Hydrogen lines are often used to trace mass accretion in young stars, but recent observations suggest that they could instead trace mass outflow in a disk wind.Aims. Obtaining direct constraints on the HI line formation regions is crucial in order to disentangle the different models. We present high angular and spectral resolution observations of the Hα line of the Herbig Ae star AB Aur to probe the origin of this line at sub-AU scales, and to place constraints on the geometry of the emitting region.Methods. We use the visible spectrograph VEGA at the CHARA long-baseline optical array to resolve the AB Aur circumstellar environment from spectrally resolved interferometric measurements across the Hα emission line. We developed a 2D radiative transfer model to fit the emission line profile and the spectro-interferometric observables. The model includes the combination of a Blandford & Payne magneto-centrifugal disk wind and a magnetospheric accretion flow.Results. We measure a visibility decrease within the Hα line, indicating that we clearly resolve the Hα formation region. We derive a Gaussian half width at half maximum between 0.05 and 0.15 AU in the core of the line, which indicates that the bulk of the Hα emission has a size scale intermediate between the disk inner truncation radius and the dusty disk inner rim. A clear asymmetric differential phase signal is found with a minimum of −30° ± 15° towards the core of the line. We show that these observations are in general agreement with predictions from a magneto-centrifugal disk wind arising from the innermost regions of the disk. Better agreement, in particular with the differential phases, is found when a compact magnetospheric accretion flow is included.Conclusions. We resolve the Hα formation region in a young accreting intermediate mass star and show that both the spectroscopic and interferometric measurements can be reproduced well by a model where the bulk of Hα forms in a MHD disk wind arising from the innermost regions of the accretion disk. These findings support similar results recently obtained in the Brγ line and confirm the importance of outflows in the HI line formation processes in young intermediate mass stars.
Highlights
One of the crucial open questions in star formation is understanding the link between accretion of matter onto the star and the launching of large-scale jets
Using the Hα emission line classification of Reipurth et al (1996), 5 spectra (22%) exhibit a P Cygni profile with blueshifted absorption going below the continuum, 13 (60%) a P Cygni profile with a secondary emission peak in the blue wing less than half of the main emission peak, and 4 (18%) spectra are single-peaked
We have presented results from multi-epoch spectrointerferometric observations (22) across the Hα line of the Herbig Ae star AB Aurigae (AB Aur) conducted with the VEGA interferometer
Summary
One of the crucial open questions in star formation is understanding the link between accretion of matter onto the star and the launching of large-scale jets. We present here spectro-interferometric observations across Hα and results from new VEGA campaigns on AB Aur conducted between 2010 and 2013 with much improved sensitivity and twice the spatial resolution as in 2010 These high quality observations allow us to conduct a detailed comparison with 2D radiative transfer predictions from a more physical model combining a magneto-centrifugal disk wind and a magnetospheric accretion component. We investigate whether such a hybrid model, proposed for T Tauri stars by Lima et al (2010), can apply to the higher mass Herbig stars.
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