Revealing the sub-AU asymmetries of the inner dust rim 
 in the disk around the Herbig Ae star R Coronae Austrinae

Kraus, Stefan; Hofmann, K.-H.; Malbet, Fabien; Meilland, A.; Natta, A.; Schertl, D.; Stee, Philippe; Weigelt, G.

doi:10.1051/0004-6361/200912990

Cited by 37 publications

(44 citation statements)

References 63 publications

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“…Considering a dust sublimation temperature around 1500-2000 K (Pollack et al 1994), and the stellar properties determined by van den Ancker et al (2004), the inner edge of the dusty disk must be located at ∼4-7 AU, in agreement with our findings. An asymmetry in the inclined inner disk could explain the non-zero closure phases measured at a level similar to other Herbig AeBe stars (Kraus et al 2009;Benisty et al 2010). …”

Section: Resultssupporting

confidence: 62%

The 2008 outburst in the young stellar system Z CMa

Benisty¹,

Malbet

Dougados

et al. 2010

A&A

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Context. Accretion is a fundamental process in star formation. Although the time evolution of accretion remains a matter of debate, observations and modelling studies suggest that episodic outbursts of strong accretion may dominate the formation of the central protostar. Observing young stellar objects during these elevated accretion states is crucial to understanding the origin of unsteady accretion. Aims. Z CMa is a pre-main-sequence binary system composed of an embedded Herbig Be star, undergoing photometric outbursts, and a FU Orionis star. This system therefore provides a unique opportunity to study unsteady accretion processes. The Herbig Be component recently underwent its largest optical photometric outburst detected so far. We aim to constrain the origin of this outburst by studying the emission region of the HI Br γ line, a powerful tracer of accretion/ejection processes on the AU-scale in young stars. Methods. Using the AMBER/VLTI instrument at spectral resolutions of 1500 and 12 000, we performed spatially and spectrally resolved interferometric observations of the hot gas emitting across the Br γ emission line, during and after the outburst. From the visibilities and differential phases, we derive characteristic sizes for the Br γ emission and spectro-astrometric measurements across the line, with respect to the continuum. Results. We find that the line profile, the astrometric signal, and the visibilities are inconsistent with the signature of either a Keplerian disk or infall of matter. They are, instead, evidence of a bipolar wind, maybe partly seen through a disk hole inside the dust sublimation radius. The disappearance of the Br γ emission line after the outburst suggests that the outburst is related to a period of strong mass loss rather than a change of the extinction along the line of sight. Conclusions. Apart from the photometric increase of the system, the main consequence of the outburst is to trigger a massive bipolar outflow from the Herbig Be component. Based on these conclusions, we speculate that the origin of the outburst is an event of enhanced mass accretion, similar to those occuring in EX Ors and FU Ors.

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Section: Resultssupporting

confidence: 62%

The 2008 outburst in the young stellar system Z CMa

Benisty¹,

Malbet

Dougados

et al. 2010

A&A

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“…(a) Lagage et al (2006); (b) Marraco & Rydgren (1981); (c) Acke & van den Ancker (2006); (d) Ardila et al (2007); (e) Pontoppidan et al (2008); ( f ) de Zeeuw et al (1999); (g) Acke & van den Ancker (2004); (h) Meeus et al (1998); (i) van der Plas et al (2008); (k) Grady et al (2004); (l) Catala et al (2007); (m) Eisner et al (2004); (n) Verhoeff et al (2010); (o) van Boekel et al (2005); (q) Kraus et al (2009); (r) Forbrich et al (2006); (s) Merín et al (2004); (t) Weinberger et al (1999); (u) Fedele et al (2008); (v) Fukagawa et al (2003); (w) Kraus et al (2008); (x) Blondel & Tjin A Djie (2006); (y) van den Ancker et al (1998).…”

Section: Introductionmentioning

confidence: 99%

The structure of disks around Herbig Ae/Be stars as traced by CO ro-vibrational emission

Plas

Ancker

Waters

et al. 2015

A&A

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Aims. We study the emission and absorption of CO ro-vibrational lines in the spectra of intermediate mass pre-main-sequence stars with the aim to determine both the spatial distribution of the CO gas and its physical properties. We also aim to correlate CO emission properties with disk geometry. Methods. Using high-resolution spectra containing fundamental and first overtone CO ro-vibrational emission, observed with CRIRES on the VLT, we probe the physical properties of the circumstellar gas by studying its kinematics and excitation conditions. Results. We detect and spectrally resolve CO fundamental ro-vibrational emission in 12 of the 13 stars observed, and in two cases in absorption.Conclusions. Keeping in mind that we studied a limited sample, we find that the physical properties and spatial distribution of the CO gas correlate with disk geometry. Flaring disks show highly excited CO fundamental emission up to v u = 5, while self-shadowed disks show CO emission that is not as highly excited. Rotational temperatures range between 250-2000 K. The 13 CO rotational temperatures are lower than those of 12 CO. The vibrational temperatures in self-shadowed disks are similar to or slightly below the rotational temperatures, suggesting that thermal excitation or IR pumping is important in these lines. In flaring disks the vibrational temperatures reach as high as 6000 K, suggesting fluorescent pumping. Using a simple kinematic model we show that the CO inner radius of the emitting region is ≈10 au for flaring disks and ≤1 au for self-shadowed disks. Comparison with hot dust and other gas tracers shows that CO emission from the disks around Herbig Ae/Be stars, in contrast to T Tauri stars, does not necessarily trace the circumstellar disk up to, or inside the dust sublimation radius, R subl . Rather, the onset of the CO emission starts from ≈R subl for self-shadowed disks, to tens of R subl for flaring disks. It has recently been postulated that group I Herbig stars may be transitional disks and have gaps. Our CO observations are qualitatively in agreement with this picture. We identify the location of the CO emission in these group I disks with the inner rim of the outer disk after such a gap, and suggest that the presence of highly vibrationally excited CO emission and a mismatch between the rotational and vibrational temperature may be a proxy for the presence of moderately sized disk gaps in Herbig Ae/Be disks.

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“…Observations with the VLTI/AMBER and Keck/V2-SPR instrument support this interpretation for T Tauri and very late-type Herbig Ae stars, where the visibilities measured within the line indicate that the line emission originates from just a few stellar radii from the star (Kraus et al 2009a;Eisner et al 2010Eisner et al , 2014. However, many high-luminosity sources show a significantly more extended line-emission region, which is not consistent with a magnetospheric accretion scenario.…”

Section: Gas Kinematics Constraintsmentioning

confidence: 91%

“…More detailed studies with longer baselines were conducted on individual objects. For instance, Kraus et al (2009a) measured significant non-zero closure phase signals on R Coronae Australis. The visibility and closure phase signals also varied systematically with baseline position angle, which could be modelled with a curved rim model that takes the gas pressure-dependence of the dust sublimation temperature into account (Isella and Natta 2005).…”

Section: Disk Structure Near the Dust Sublimation Radiusmentioning

confidence: 99%

“…This extended emission can contribute up to ∼ 30% of the total H and K-band flux in some systems (e.g. Kraus et al 2009a) and is typically distributed over a few hundred milliarcseconds to a few arcseconds (Leinert et al 2001). The physical origin of the emission is still debated, but it might correspond to scattered light from the outer disk (Pinte et al 2008), from an halo in which the disk is embedded, or the walls of an outflow cone.…”

Section: Disk Structure In the Extended Diskmentioning

confidence: 99%

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The interferometric view of Herbig Ae/Be stars

Kraus

2015

Astrophys Space Sci

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In this contribution I review how optical interferometry has contributed to shaping our understanding of the class of Herbig Ae/Be stars and of their associated circumstellar disks. I discuss the evidence for an optically-thin cavity in the inner few astronomical units (au) and a "puffed-up rim" near the dust sublimation radius and how these observations helped to establish the current generation of irradiated disk models. Multi-wavelength interferometric observations also revealed systems with clear signatures of grain growth and dynamically-cleared disk gaps, tracing important stages of disk evolution and of ongoing planet formation. I discuss the new opportunities provided by spectro-interferometry, which enables detailed studies on the gas distribution and velocity field on sub-au scales, resulting in constrains on the accretion properties of the system and the disk excitation structure. Finally, I outline some of the open questions and loose ends in current interferometric studies, and how these might point towards new disk physics.

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Revealing the sub-AU asymmetries of the inner dust rim in the disk around the Herbig Ae star R Coronae Austrinae

Cited by 37 publications

References 63 publications

The 2008 outburst in the young stellar system Z CMa

The 2008 outburst in the young stellar system Z CMa

The structure of disks around Herbig Ae/Be stars as traced by CO ro-vibrational emission

The interferometric view of Herbig Ae/Be stars

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