The structure of disks around Herbig Ae/Be stars as traced by CO ro-vibrational emission
Author
dc.contributor.author
Van der Plas, Gerrit
Author
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Ancker, M. E. van den
Author
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Waters, L. B. F. M.
Author
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Dominik, C.
Admission date
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2015-08-07T14:36:21Z
Available date
dc.date.available
2015-08-07T14:36:21Z
Publication date
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2015
Cita de ítem
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Astronomy & Astrophysics 574, A75 (2015)
en_US
Identifier
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1432-0746
Identifier
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DOI: 10.1051/0004-6361/201425052
Identifier
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https://repositorio.uchile.cl/handle/2250/132483
General note
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Artículo de publicación ISI
en_US
Abstract
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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 vu = 5, while self-shadowed
disks show CO emission that is not as highly excited. Rotational temperatures range between 250–2000 K. The 13CO rotational
temperatures are lower than those of 12CO. 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, Rsubl. Rather, the onset of the CO emission starts from Rsubl for
self-shadowed disks, to tens of Rsubl 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.