A 10 $\mathsf{\mu}$m spectroscopic survey of Herbig Ae star disks: Grain growth and crystallization

Boekel, R. van; Min, M.; Waters, L. B. F. M.; Koter, A. de; Dominik, C.; Ancker, M. E. van den; Bouwman, J.

doi:10.1051/0004-6361:20042339

Cited by 278 publications

(433 citation statements)

References 62 publications

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“…Figure 13c shows that the dust in the warm inner regions of protoplanetary disks generally contains a higher fraction of crystalline material than the dust in cooler regions. This is consistent with earlier findings (e.g., van Boekel et al 2004;Meeus et al 2009). …”

Section: (B) Dust Properties Of Disks Around Cool T Tauri Starssupporting

confidence: 94%

“…The shape and the strength of the 10 μm silicate feature were found to be correlated and this was interpreted as evidence for grain growth in disks (van Boekel et al 2005;Kessler-Silacci et al 2006;Bouwman et al 2008). The Spitzer/IRS has provided spectra of many young objects, covering the wavelength range from 5.3 to 38 μm.…”

Section: Introductionmentioning

confidence: 89%

“…This may be a contrast effect: because of the very low luminosity of ID#10, its 10 μm silicate feature arises mainly in the inner ∼0.5 AU of the disk. The central regions of disks can be highly crystalline (van Boekel et al 2004), possibly leading to very high apparent crystallinities if only the very central disk regions contribute to the part of the spectrum used in the mineralogical analysis (see also Apai et al 2005). In Fig.…”

Section: The Dust Properties Of Disksmentioning

confidence: 99%

“…The most convincing evidence that silicates are present in the protoplanetary disks is the strong "10 μm feature" in midinfrared spectra of Herbig Ae/Be and T Tauri stars (Cohen & Witteborn 1985;Natta et al 2000;Bouwman et al 2001Bouwman et al , 2003van Boekel et al 2004;van Boekel et al 2005). This feature is emitted by silicate grains with sizes of up to several microns that reside in the optically thin surface layers of the disk (Men'shchikov & Henning 1997;Chiang & Goldreich 1997).…”

Section: Introductionmentioning

confidence: 99%

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Young stars inϵChamaleontis and their disks: disk evolution in sparse associations

Fang

Boekel

Bouwman

et al. 2012

A&A

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Context. The nearby young stellar association Cha has an estimated age of 3-5 Myr, making it an ideal laboratory to study the disk dissipation process and provide empirical constraints on the timescale of planet formation. Aims. We wish to complement existing optical and near-infrared data of the Cha association, which provide the stellar properties of its members, with mid-infrared data that probe the presence, geometry, and mineralogical composition of protoplanetary disks around individual stars. Methods. We combine the available literature data with our Spitzer/IRS spectroscopy and VLT/VISIR imaging data. We use proper motions to refine the membership of Cha. Masses and ages of individual stars are estimated by fitting model atmospheres to the optical and near-infrared photometry, followed by placement in the Hertzsprung-Russell diagram. The Spitzer/IRS spectra are analyzed using the two-layer temperature distribution spectral decomposition method. Results. Two stars previously identified as members, CXOU J120152.8 and 2MASS J12074597, have proper motions that are very different from those of the other stars. But other observations suggest that the two stars are still young and thus might still be related to Cha. HD 104237C is the lowest mass member of Cha with an estimated mass of ∼13-15 Jupiter masses. The very low mass stars USNO-B120144.7 and 2MASS J12005517 show globally depleted spectral energy distributions, pointing at strong dust settling. 2MASS J12014343 may have a disk with a very specific inclination, where the central star is effectively screened by the cold outer parts of a flared disk, but the 10 μm radiation of the warm inner disk can still reach us. We find that the disks in sparse stellar associations are dissipated more slowly than those in denser (cluster) environments. We detect C 2 H 2 rovibrational band around 13.7 μm on the IRS spectrum of USNO-B120144.7. We find strong signatures of grain growth and crystallization in all Cha members with 10 μm features detected in their IRS spectra. We combine the dust properties derived in the Cha sample with those found using identical or similar methods in the MBM 12, Coronet, η Cha associations, and in the cores-to-disks legacy program. We find that disks around low-mass young stars show a negative radial gradient in the mass-averaged grain size and mass fraction of crystalline silicates. A positive correlation exists between the mass-averaged grain sizes of amorphous silicates and the accretion rates if the latter is above ∼10 −9 M yr −1 , possibly indicating that those disks are sufficiently turbulent to prevent grains of several microns in size to sink into the disk interior.

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Section: (B) Dust Properties Of Disks Around Cool T Tauri Starssupporting

confidence: 94%

Section: Introductionmentioning

confidence: 89%

Section: The Dust Properties Of Disksmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Young stars inϵChamaleontis and their disks: disk evolution in sparse associations

Fang

Boekel

Bouwman

et al. 2012

A&A

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“…Third, the grain sizes and properties may be very different from those found in clouds. In particular, there is strong evidence from infrared observations that grains in the upper disk layers have grown from ∼ 0.1 µm to a few µm in size regardless of the spectral type of the star (e.g., [71,32]). Figure 2 illustrates this growth using recent Spitzer Space Telescope spectra of the 10 and 20 µm silicate feature.…”

Section: Photoprocesses In Disksmentioning

confidence: 99%

Photoprocesses in protoplanetary disks

2006

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Circumstellar disks are exposed to intense ultraviolet (UV) radiation from the young star. In the inner disks, the UV radiation can be enhanced by more than seven orders of magnitude compared with the average interstellar radiation field, resulting in a physical and chemical structure that resembles that of a dense photon-dominated region (PDR). This intense UV field affects the chemistry, the vertical structure of the disk, and the gas temperature, especially in the surface layers. The parameters which make disks different from more traditional PDRs are discussed, including the shape of the UV radiation field, grain growth, the absence of PAHs, the gas/dust ratio and the presence of inner holes. Illustrative infrared spectra from the Spitzer Space Telescope are shown. New photodissociation cross sections for selected species, including simple ions, are presented. Also, a summary of cross sections at the Lyman α 1216Å line, known to be strong for some T Tauri stars, is made. Photodissociation and ionization rates are computed for different radiation fields with color temperatures ranging from 30000 to 4000 K and grain sizes up to a few µm. The importance of a proper treatment of the photoprocesses is illustrated for the transitional disk toward HD 141569A which includes grain growth.

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Accretion Disks Before (?) the Main Planet Formation Phase

Dominik

Astrophysics in the Next Decade

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A 10 $\mathsf{\mu}$m spectroscopic survey of Herbig Ae star disks: Grain growth and crystallization

Cited by 278 publications

References 62 publications

Young stars inϵChamaleontis and their disks: disk evolution in sparse associations

Young stars inϵChamaleontis and their disks: disk evolution in sparse associations

Photoprocesses in protoplanetary disks

Accretion Disks Before (?) the Main Planet Formation Phase

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