2022
DOI: 10.1051/0004-6361/202141932
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Evolution of dust in protoplanetary disks of eruptive stars

Abstract: Aims. Luminosity bursts in young FU Orionis-type stars warm up the surrounding disks of gas and dust, thus inflicting changes on their morphological and chemical composition. In this work, we aim at studying the effects that such bursts may have on the spatial distribution of dust grain sizes and the corresponding spectral index in protoplanetary disks. Methods. We use the numerical hydrodynamics code FEOSAD, which simulates the co-evolution of gas, dust, and volatiles in a protoplanetary disk, taking dust gro… Show more

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Cited by 20 publications
(13 citation statements)
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“…First, they are the seeds of planet formation. While their characteristic size is submicron in the interstellar medium (ISM) (Mathis et al 1977), they grow by coagulation during the collapse and can reach sizes larger than 10 µm in the early stages of protostellar collapse (Guillet et al 2020;Silsbee et al 2020;Tsukamoto et al 2021;Vorobyov et al 2022;Bate 2022). Observations also suggest they reach these sizes (and possibly larger ones) in the envelopes of Class 0-I objects (Kwon et al 2009;Miotello et al 2014;Le Gouellec et al 2019;Galametz et al 2019).…”
Section: Introductionmentioning
confidence: 99%
See 1 more Smart Citation
“…First, they are the seeds of planet formation. While their characteristic size is submicron in the interstellar medium (ISM) (Mathis et al 1977), they grow by coagulation during the collapse and can reach sizes larger than 10 µm in the early stages of protostellar collapse (Guillet et al 2020;Silsbee et al 2020;Tsukamoto et al 2021;Vorobyov et al 2022;Bate 2022). Observations also suggest they reach these sizes (and possibly larger ones) in the envelopes of Class 0-I objects (Kwon et al 2009;Miotello et al 2014;Le Gouellec et al 2019;Galametz et al 2019).…”
Section: Introductionmentioning
confidence: 99%
“…The dust evolution used to be pre-processed or post-processed with no self-consistent feedback on the dynamics (Rossi et al 1991;Dullemond & Dominik 2005;Zhao et al 2016;Marchand et al 2020). Recently, more and more studies include the growth of grains in their hydrodynamics simulations (Tsukamoto et al 2021;Vericel et al 2021;Vorobyov et al 2022;Bate 2022). In Marchand et al (2021, hereafter Paper I), we presented a simple and fast method to track coagulation in a self-consistent way that is particularly suited for modeling star formation.…”
Section: Introductionmentioning
confidence: 99%
“…While we did not include ices in our calculations, the motion of the 𝑇 = 105 K iso-temperature line in our simulations is consistent with these observations. The water snow-line has a non-circular shape, which has also been found for outbursts in gravitationally unstable discs Vorobyov et al (2022). This is a crude comparison though as in practice the snow-line depends on the temperature as well as the pressure (see e.g.…”
Section: High Temperature Processingmentioning
confidence: 57%
“…Variable dust component: The dust-to-gas mass ratio, f dust , in this study is kept constant at the respective stellar metallicity value trough out the simulation and over the disk's radial extent. While this assumption might be reasonable in the first step, the dust fraction can differ within the disk over time due to a great number of processes, such as coagulation, drift, fragmentation, and vertical settling (e.g., Testi et al 2014;Vorobyov et al 2022).…”
Section: Model Limitationsmentioning
confidence: 99%