The structure of disks around intermediate-mass young stars from mid-infrared interferometry

Menu, J.; Boekel, R. van; Henning, Thomas; Leinert, Ch.; Waelkens, Christoffel; Waters, L.B.F.M.

doi:10.1051/0004-6361/201525654

Cited by 116 publications

(209 citation statements)

References 126 publications

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“…Interferometric observations reveal radial gaps on (sub-)au scales in both (Chen et al 2012;Schegerer et al 2013;Menu et al 2015). They are thus small-scale transitional disks with outer disks similar to group II sources.…”

Section: Resultsmentioning

confidence: 89%

“…Initially, group I was thought to evolve to group II as dust particles grew Appendix A is available in electronic form at http://www.aanda.org and settled (Meeus et al 2001;Dullemond & Dominik 2004a,b). The emerging view from recent debates is that group I disks are transitional, i.e., have radial cavities or gaps strongly depleted in millimetre-sized dust and perhaps gas (e.g., Keane et al 2014;Maaskant et al 2014;Banzatti & Pontoppidan 2015;Menu et al 2015;van der Plas et al 2015). As yet, no group II source is known to be a transition disk (TD), while all resolved TDs are group I sources.…”

Section: Introductionmentioning

confidence: 99%

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Fingerprints of giant planets in the photospheres of Herbig stars

Kama

Folsom

Pinilla

2015

A&A

109

152

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Around 2% of all A stars have photospheres depleted in refractory elements. This is hypothesised to arise from gas being accreted more efficiently than dust, but the specific processes and the origin of the material -circum-or interstellar -are not known. The same depletion is seen in 30% of young, disk-hosting Herbig Ae/Be stars. We investigate whether the chemical peculiarity originates in a circumstellar disk. Using a sample of systems for which both the stellar abundances and the protoplanetary disk structure are known, we find that stars hosting warm, flaring group I disks typically have Fe, Mg and Si depletions of 0.5 dex compared to the solar-like abundances of stars hosting cold, flat group II disks. The volatile, C and O, abundances in both sets are identical. Group I disks are generally transitional, having radial cavities depleted in millimetre-sized dust grains, while those of group II are usually not. Thus we propose that the depletion of heavy elements emerges as Jupiter-like planets block the accretion of part of the dust, while gas continues to flow towards the central star. We calculate gas to dust ratios for the accreted material and find values consistent with models of disk clearing by planets. Our results suggest that giant planets of ∼0.1 to 10 M Jup are hiding in at least 30% of Herbig Ae/Be disks.

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Section: Resultsmentioning

confidence: 89%

Section: Introductionmentioning

confidence: 99%

Fingerprints of giant planets in the photospheres of Herbig stars

Kama

Folsom

Pinilla

2015

A&A

109

152

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“…The photospheric template, where used for photospheric correction, is shown in magenta at the top, broadened and veiled. Maaskant et al 2013;Menu et al 2015), as well as to recent model explorations (Antonellini et al 2016).…”

Section: Discussionmentioning

confidence: 98%

“…One major implication of this analysis is that the low frequency of water vapor detections in disks around  > M 1.5  M is found to be linked to inner disk regions depleted in molecular gas out to or even beyond the water snow line, differently from most disks around solar-mass stars. Other independent techniques find signatures of inner holes in dust emission in a growing number of disks around intermediatemass stars (e.g., Maaskant et al 2013;Menu et al 2015). With the analysis of disks that have CO emission observed at 4.7 μm and H 2 O at 2.9 μm and/or 10-33 μm (Table 6), we also find that the depletion scenario is not limited to the known transitional disks or to disks around intermediate-mass stars.…”

Section: Water Vapor and The Depletion Of Inner Disksmentioning

confidence: 99%

The Depletion of Water During Dispersal of Planet-Forming Disk Regions

Banzatti

Pontoppidan

Salyk

et al. 2017

ApJ

119

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We present a new velocity-resolved survey of 2.9 μm spectra of hot H 2 O and OH gas emission from protoplanetary disks, obtained with the Cryogenic Infrared Echelle Spectrometer at the VLT (R ∼ 96,000). With the addition of archival Spitzer-IRS spectra, this is the most comprehensive spectral data set of water vapor emission from disks ever assembled. We provide line fluxes at 2.9-33 μm that probe from the dust sublimation radius at ∼0.05 au out to the region of the water snow line. With a combined data set for 55 disks, we find a new correlation between H 2 O line fluxes and the radius of CO gas emission, as measured in velocity-resolved 4.7 μm spectra (Rco), which probes molecular gaps in inner disks. We find that H 2 O emission disappears from 2.9 μm (hotter water) to 33 μm (colder water) as R co increases and expands out to the snow line radius. These results suggest that the infrared water spectrum is a tracer of inside-out water depletion within the snow line. It also helps clarify an unsolved discrepancy between water observations and models by finding that disks around stars ofgenerally have inner gaps with depleted molecular gas content. We measure radial trends in H 2 O, OH, and CO line fluxes that can be used as benchmarks for models to study the chemical composition and evolution of planet-forming disk regions at 0.05-20 au. We propose that JWST spectroscopy of molecular gas may be used as a probe of inner disk gas depletion, complementary to the larger gaps and holes detected by direct imaging and by ALMA.

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“…The observation log is shown in Table 1. For modeling and interpretation, we complemented our near-infrared AMBER data with archival mid-infrared MIDI data (published in the survey paper of Menu et al 2015). We re-reduced this data set of five MIDI measurements using custom IDL routines (Kishimoto et al 2011) that incorporates parts of the standard software EWS 2 .…”

Section: Observations and Data Reductionmentioning

confidence: 99%

Resolving the inner disk of UX Orionis

Kreplin

Madlener

Chen

et al. 2016

A&A

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Aims. The cause of the UX Ori variability in some Herbig Ae/Be stars is still a matter of debate. Detailed studies of the circumstellar environment of UX Ori objects (UXORs) are required to test the hypothesis that the observed drop in photometry might be related to obscuration events. Methods. Using near-and mid-infrared interferometric AMBER and MIDI observations, we resolved the inner circumstellar disk region around UX Ori. Results. We fitted the K-, H-, and N-band visibilities and the spectral energy distribution (SED) of UX Ori with geometric and parametric disk models. The best-fit K-band geometric model consists of an inclined ring and a halo component. We obtained a ring-fit radius of 0.45 ± 0.07 AU (at a distance of 460 pc), an inclination of 55.6 ± 2.4 • , a position angle of the system axis of 127.5 ± 24.5 • , and a flux contribution of the over-resolved halo component to the total near-infrared excess of 16.8 ± 4.1%. The best-fit N-band model consists of an elongated Gaussian with a HWHM ∼ 5 AU of the semi-major axis and an axis ration of a/b ∼ 3.4 (corresponding to an inclination of ∼72 • ). With a parametric disk model, we fitted all near-and mid-infrared visibilities and the SED simultaneously. The model disk starts at an inner radius of 0.46 ± 0.06 AU with an inner rim temperature of 1498 ± 70 K. The disk is seen under an nearly edge-on inclination of 70 ± 5 • . This supports any theories that require high-inclination angles to explain obscuration events in the line of sight to the observer, for example, in UX Ori objects where orbiting dust clouds in the disk or disk atmosphere can obscure the central star.

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The structure of disks around intermediate-mass young stars from mid-infrared interferometry

Cited by 116 publications

References 126 publications

Fingerprints of giant planets in the photospheres of Herbig stars

Fingerprints of giant planets in the photospheres of Herbig stars

The Depletion of Water During Dispersal of Planet-Forming Disk Regions

Resolving the inner disk of UX Orionis

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