Your search keyword '"Birnstiel T"' showing total 4 results

1. PROTOPLANETARY DISK STRUCTURE WITH GRAIN EVOLUTION: THE ANDES MODEL.

Author

AKIMKIN, V., ZHUKOVSKA, S., WIEBE, D., SEMENOV, D., PAVLYUCHENKOV, YA., VASYUNIN, A., BIRNSTIEL, T., and HENNING, TH.

Subjects

PROTOPLANETARY disks, RADIATIVE transfer, DUST, GAS phase reactions, CHEMICAL structure, ASTROPHYSICS research

Abstract

We present a self-consistent model of a protoplanetary disk: "ANDES" ("AccretioN disk with Dust Evolution and Sedimentation"). ANDES is based on a flexible and extendable modular structure that includes (1) a 1+1D frequency-dependent continuum radiative transfer module, (2) a module to calculate the chemical evolution using an extended gas-grain network with UV/X-ray-driven processes and surface reactions, (3) a module to calculate the gas thermal energy balance, and (4) a 1+1D module that simulates dust grain evolution. For the first time, grain evolution and time-dependent molecular chemistry are included in a protoplanetary disk model. We find that grain growth and sedimentation of large grains onto the disk midplane lead to a dust-depleted atmosphere. Consequently, dust and gas temperatures become higher in the inner disk (R ≲ 50 AU) and lower in the outer disk (R ≳ 50 AU), in comparison with the disk model with pristine dust. The response of disk chemical structure to the dust growth and sedimentation is twofold. First, due to higher transparency a partly UV-shielded molecular layer is shifted closer to the dense midplane. Second, the presence of big grains in the disk midplane delays the freeze-out of volatile gas-phase species such as CO there, while in adjacent upper layers the depletion is still effective. Molecular concentrations and thus column densities of many species are enhanced in the disk model with dust evolution, e.g., CO2, NH2CN, HNO, H2O, HCOOH, HCN, and CO. We also show that time-dependent chemistry is important for a proper description of gas thermal balance. [ABSTRACT FROM AUTHOR]

Published

2013

2. THE TW Hya DISK AT 870 µm: COMPARISON OF CO AND DUST RADIAL STRUCTURES.

Author

Andrews, Sean M., Wilner, David J., Hughes, A. M., Chunhua Qi, Rosenfeld, Katherine A., Öberg, Karin I., Birnstiel, T., Espaillat, Catherine, Cieza, Lucas A., Williams, Jonathan P., Shin-Yi Lin, and Ho, Paul T. P.

Subjects

PROTOPLANETARY disks, ACCRETION (Astrophysics), SPECTRAL energy distribution, SPECTRUM analysis, ORIGIN of the solar system

Abstract

We present high-resolution (0".3 = 16 AU), high signal-to-noise ratio Submillimeter Array observations of the 870 µm (345 GHz) continuum and CO J = 3 - 2 line emission from the protoplanetary disk around TW Hya. Using continuum and line radiative transfer calculations, these data and the multiwavelength spectral energy distribution are analyzed together in the context of simple two-dimensional parametric disk structure models. Under the assumptions of a radially invariant dust population and gas-to-dust mass ratio, we are unable to simultaneously reproduce the CO and dust observations with model structures that employ either a single, distinct outer boundary or a smooth (exponential) taper at large radii. Instead, we find that the distribution of millimeter-sized dust grains in the TW Hya disk has a relatively sharp edge near 60 AU, contrary to the CO emission (and optical/infrared scattered light) that extends to a much larger radius of at least 215 AU. We discuss some possible explanations for the observed radial distribution of millimeter-sized dust grains and the apparent CO-dust size discrepancy, and suggest that they may be hallmarks of substructure in the dust disk or natural signatures of the growth and radial drift of solids that might be expected for disks around older pre-main-sequence stars like TW Hya. [ABSTRACT FROM AUTHOR]

Published

2012

3. RESOLVED MULTIFREQUENCY RADIO OBSERVATIONS OF GG Tau.

Author

Andrews, Sean M., Chandler, Claire J., Isella, Andrea, Birnstiel, T., Rosenfeld, K. A., Wilner, D. J., Pérez, L. M., Ricci, L., Carpenter, J. M., Calvet, N., Corder, S. A., Deller, A. T., Dullemond, C. P., Greaves, J. S., Harris, R. J., Henning, Th., Kwon, W., Lazio, J., Linz, H., and Mundy, L. G.

Subjects

PROTOPLANETARY disks, PLANETARY research, STAR clusters, PARTICLE size distribution, STELLAR mass

Abstract

We present subarcsecond resolution observations of continuum emission associated with the GG Tau quadruple star system at wavelengths of 1.3, 2.8, 7.3, and 50 mm. These data confirm that the GG Tau A binary is encircled by a circumbinary ring at a radius of 235 AU with a FWHM width of ∼60 AU. We find no clear evidence for a radial gradient in the spectral shape of the ring, suggesting that the particle size distribution is spatially homogeneous on angular scales ≳0.″1. A central point source, likely associated with the primary component (GG Tau Aa), exhibits a composite spectrum from dust and free-free emission. Faint emission at 7.3 mm is observed toward the low-mass star GG Tau Ba, although its origin remains uncertain. Using these measurements of the resolved, multifrequency emission structure of the GG Tau A system, models of the far-infrared to radio spectrum are developed to place constraints on the grain size distribution and dust mass in the circumbinary ring. The non-negligible curvature present in the ring spectrum implies a maximum particle size of 1-10 mm, although we are unable to place strong constraints on the distribution shape. The corresponding dust mass is 30-300 M⊕, at a temperature of 20-30 K. We discuss how this significant concentration of relatively large particles in a narrow ring at a large radius might be produced in a local region of higher gas pressures (i.e., a particle “trap”) located near the inner edge of the circumbinary disk. [ABSTRACT FROM AUTHOR]

Published

2014

4. IMPACT OF GRAIN EVOLUTION ON THE CHEMICAL STRUCTURE OF PROTOPLANETARY DISKS.

Author

Vasyunin, A. I., Wiebe, D. S., Birnstiel, T., Zhukovska, S., Henning, T., and Dullemond, C. P.

Published

2011