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Dust properties across the Co snowline in the HD 163296 disk from ALMA and VLA observations

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posted on 2024-08-06, 10:52 authored by G. Guidi, M. Tazzari, L. Testi, I. De Gregorio-Monsalvo, C. J. Chandler, L. Pérez, A. Isella, A. Natta, S. Ortolani, Th Henning, S. Corder, H. Linz, S. Andrews, D. Wilner, L. Ricci, J. Carpenter, A. Sargent, L. Mundy, S. Storm, N. Calvet, C. Dullemond, J. Greaves, J. Lazio, Adam DellerAdam Deller, W. Kwon
Context. To characterize the mechanisms of planet formation it is crucial to investigate the properties and evolution of protoplanetary disks around young stars, where the initial conditions for the growth of planets are set. The high spatial resolution of Atacama Large Millimeter/submillimeter Array (ALMA) and Karl G. Jansky Very Large Array (VLA) observations now allows the study of radial variations of dust properties in nearby resolved disks and the investigation of the early stages of grain growth in disk midplanes. Aims. Our goal is to study grain growth in the well-studied disk of the young, intermediate-mass star HD 163296 where dust processing has already been observed and to look for evidence of growth by ice condensation across the CO snowline, which has already been identified in this disk with ALMA. Methods. Under the hypothesis of optically thin emission, we compare images at different wavelengths from ALMA and VLA to measure the opacity spectral index across the disk and thus the maximum grain size. We also use a Bayesian tool based on a two-layer disk model to fit the observations and constrain the dust surface density. Results. The measurements of the opacity spectral index indicate the presence of large grains and pebbles (≥1 cm) in the inner regions of the disk (inside ~50 AU) and smaller grains, consistent with ISM sizes, in the outer disk (beyond 150 AU). Re-analyzing ALMA Band 7 science verification data, we find (radially) unresolved excess continuum emission centered near the location of the CO snowline at ~90 AU. Conclusions. Our analysis suggests a grain size distribution consistent with an enhanced production of large grains at the CO snowline and consequent transport to the inner regions. Our results combined with the excess in infrared scattered light suggests there is a structure at 90 AU involving the whole vertical extent of the disk. This could be evidence of small scale processing of dust at the CO snowline.

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ISSN

1432-0746

Journal title

Astronomy and Astrophysics

Volume

588

Article number

article no. A112

Pagination

a112-

Publisher

EDP Sciences

Copyright statement

Copyright © 2016 ESO. The published version of this publication is reproduced with permission from Astronomy & Astrophysics.

Language

eng

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