Accretion Disks around Young Objects. II. Tests of Well‐mixed Models with ISM Dust

D’Alessio, Paola; Calvet, Nuria; Hartmann, L.; Lizano, Susana; Cantó, J.

doi:10.1086/308103

Cited by 428 publications

(317 citation statements)

References 54 publications

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“…Recent detailed models of disk structure Ðnd that the scale height exponent varies with radius in the inner regions but follows a similar power law beyond a few AU (DÏAlessio et al 1999 ;Chiang & Goldreich 1997 ;Bell et al 1997). The scattered-light models of Burrows et al (1996) and demonstrated that high-resolution imaging enables the determination of the disk scale height at large radii.…”

Section: Disk and Stellar Structurementioning

confidence: 96%

High‐Resolution Near‐Infrared Images and Models of the Circumstellar Disk in HH 30

Cotera

Whitney

Young

et al. 2001

ApJ

153

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We present Hubble Space T elescope near-infrared camera and multiobject spectrometer observations of the reÑection nebulosity associated with the T Tauri star HH 30. The images show the scattered-light pattern characteristic of a highly inclined, optically thick disk with a prominent dust lane whose width decreases with increasing wavelength. The reÑected nebulosity exhibits a lateral asymmetry in the upper lobe on the opposite side to that reported in previously published Wide Field Planetary Camera 2 images. The radiation transfer model that most closely reproduces the data has a Ñared accretion disk with dust grains larger than standard interstellar medium grains by a factor of approximately 2.1. A single hot spot on the stellar surface provides the necessary asymmetry to Ðt the images and is consistent with previous modeling of the light curve and images. Photometric analysis results in an estimated extinction of however, since the photometry measures only scattered light rather than direct A V Z 80 ; stellar Ñux, this a lower limit. The radiative transfer models require an extinction of A V \ 7900.

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Section: Disk and Stellar Structurementioning

confidence: 96%

High‐Resolution Near‐Infrared Images and Models of the Circumstellar Disk in HH 30

Cotera

Whitney

Young

et al. 2001

ApJ

153

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“…The gas density decreases radially outward as a power law of r, and in the vertical direction it decreases as z increases in roughly an exponential way. The gas heating across the disk Article published by EDP Sciences is dominated by the stellar irradiation of the surface layers at large radii (r ≥ 10 AU), thus, the kinetic temperature increases with z, while at small radii (r ∼ a few AU) viscous dissipation may become an important heating mechanism in the midplane regions (D'Alessio et al 1998(D'Alessio et al , 1999. A flared disk is significantly exposed to the strong UV field from the central star.…”

Section: Chemical Modelmentioning

confidence: 99%

Formation of simple organic molecules in inner T Tauri disks

Agúndez¹,

Cernicharo²,

Goicoechea³

2008

A&A

155

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Aims. We present time dependent chemical models for a dense and warm O-rich gas exposed to a strong, far ultraviolet (FUV) field aimed at exploring the formation of simple organic molecules in the inner regions of protoplanetary disks around T Tauri stars.Methods. An up-to-date chemical network is used to compute the evolution of molecular abundances. Reactions of H 2 with small organic radicals such as C 2 and C 2 H, which are not included in current astrochemical databases, overcome their moderate activation energies at warm temperatures and become very important for the gas phase synthesis of C-bearing molecules.Results. The photodissociation of CO and release of C triggers the formation of simple organic species such as C 2 H 2 , HCN, and CH 4 . In timescales between 1 and 10 4 years, depending on the density and FUV field, a steady state is reached in the model in which molecules are continuously photodissociated, but also formed, mainly through gas phase chemical reactions involving H 2 . Conclusions. The application of the model to the upper layers of inner protoplanetary disks predicts large gas phase abundances of C 2 H 2 and HCN. The implied vertical column densities are as large as several 10 16 cm −2 in the very inner disk (<1 AU), in good agreement with the recent infrared observations of warm C 2 H 2 and HCN in the inner regions of IRS 46 and GV Tau disks. We also compare our results with previous chemical models studying the photoprocessing in the outer disk regions, and find that the gas phase chemical composition in the upper layers of the inner terrestrial zone (a few AU) is predicted to be substantially different from that in the upper layers of the outer disk (>50 AU).

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“…These models assumed that a single temperature characterizes any given radius in the disk. Vertical temperature structure in the disk was Ðrst considered by Calvet et al (1991Calvet et al ( , 1992, with subsequent analysis by DÏAlessio et al (1998DÏAlessio et al ( , 1999, CG97, and CG99. In these models, absorption of stellar radiation occurs only in surface layers of the disk, while any heating due to viscous dissipation (accretion) occurs mainly in the midplane.…”

Section: Existing Disk Modelsmentioning

confidence: 99%

“…In these models, absorption of stellar radiation occurs only in surface layers of the disk, while any heating due to viscous dissipation (accretion) occurs mainly in the midplane. DÏAlessio et al (1998DÏAlessio et al ( , 1999 compute disk emission spectra assuming identical gas and dust temperature structures, whereas CG9799 essentially ignore the gas. The key issue is whether dust opacity and emissivity at the disk surface overwhelms the gas contribution at all wavelengths, in which case the gas may be ignored.…”

Section: Existing Disk Modelsmentioning

confidence: 99%

“…As expected (CG97 ; CG99), models without a superheated dust layer produced less K-band emission than our model, exacerbating the discrepancy with veiling measurements that are generally higher than expected in any model. DÏAlessio et al (1998DÏAlessio et al ( , 1999 computed detailed disk structure models, generally matching an average CTTS SED from optical to millimeter wavelengths, assuming a disk that extends to the stellar surface. Separate star and disk SEDs are presented only in Figure 13 of DÏAlessio et al (1998) Figure 13 of DÏAlessio et al (1998) implies r K D 0.4.…”

Section: Dust Destruction and Inner Disk Holesmentioning

confidence: 99%

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New Infrared Veiling Measurements and Constraints on Accretion Disk Models for Classical T Tauri Stars

Johns–Krull

Valenti

2001

ApJ

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We analyze K-band infrared (IR) spectra of 14 classical and nine naked T Tauri stars. Using Ðve lines of CO, we determine v sin i and show that IR and optical measurements agree well. From this we conclude that K-band absorption lines generally form in the stellar photosphere. Using line equivalent widths, we measure K-band veiling for classical T Tauri stars in our sample. Accretion disk models constrained by existing stellar and accretion parameters yield testable predictions for K-band veiling. In the context of these models, we examine sources of IR emission from the disk. The importance of disk reprocessing of emission from the accretion shock as material strikes the stellar surface is shown. We then show that current models constrained by the most recent estimates of mass accretion have a difficult time reproducing many of our high-veiling results. We suggest that dust out of the plane of the accretion disk (possibly in the magnetospheric Ñow itself) may account for much of the emission missing in the models.

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Accretion Disks around Young Objects. II. Tests of Well‐mixed Models with ISM Dust

Cited by 428 publications

References 54 publications

High‐Resolution Near‐Infrared Images and Models of the Circumstellar Disk in HH 30

High‐Resolution Near‐Infrared Images and Models of the Circumstellar Disk in HH 30

Formation of simple organic molecules in inner T Tauri disks

New Infrared Veiling Measurements and Constraints on Accretion Disk Models for Classical T Tauri Stars

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