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Fast formation of large ice pebbles after FU Orionis outbursts

Ros, Katrin LU and Johansen, Anders LU (2024) In Astronomy and Astrophysics 686.
Abstract

During their formation, nascent planetary systems are subject to FU Orionis outbursts that heat a substantial part of the disc. This causes water ice in the affected part of the disc to sublimate as the ice line moves outwards to several to tens of astronomical units. In this paper, we investigate how the subsequent cooling of the disc impacts the particle sizes. We calculate the resulting particle sizes in a disc model with cooling times between 100 and 1000 yr, corresponding to typical FU Orionis outbursts. As the disc cools and the ice line retreats inwards, water vapour forms icy mantles on existing silicate particles. This process is called heterogeneous nucleation. The nucleation rate per surface area of silicate substrate... (More)

During their formation, nascent planetary systems are subject to FU Orionis outbursts that heat a substantial part of the disc. This causes water ice in the affected part of the disc to sublimate as the ice line moves outwards to several to tens of astronomical units. In this paper, we investigate how the subsequent cooling of the disc impacts the particle sizes. We calculate the resulting particle sizes in a disc model with cooling times between 100 and 1000 yr, corresponding to typical FU Orionis outbursts. As the disc cools and the ice line retreats inwards, water vapour forms icy mantles on existing silicate particles. This process is called heterogeneous nucleation. The nucleation rate per surface area of silicate substrate strongly depends on the degree of super-saturation of the water vapour in the gas. Fast cooling results in high super-saturation levels, high nucleation rates, and limited condensation growth because the main ice budget is spent in the nucleation. Slow cooling, on the other hand, leads to rare ice nucleation and efficient growth of ice-nucleated particles by subsequent condensation. We demonstrate that close to the quiescent ice line, pebbles with a size of about centimetres to decimetres form by this process. The largest of these are expected to undergo cracking collisions. However, their Stokes numbers still reach values that are high enough to potentially trigger planetesimal formation by the streaming instability if the background turbulence is weak. Stellar outbursts may thus promote planetesimal formation around the water ice line in protoplanetary discs.

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author
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organization
publishing date
type
Contribution to journal
publication status
published
subject
keywords
Planet-disk interactions, Planets and satellites: formation, Protoplanetary disks
in
Astronomy and Astrophysics
volume
686
article number
A237
publisher
EDP Sciences
external identifiers
  • scopus:85196632786
ISSN
0004-6361
DOI
10.1051/0004-6361/202348101
language
English
LU publication?
yes
id
9e37acaf-06ab-45ec-a20b-2dfc1936d8ea
date added to LUP
2024-08-21 12:33:40
date last changed
2024-08-21 12:34:31
@article{9e37acaf-06ab-45ec-a20b-2dfc1936d8ea,
  abstract     = {{<p>During their formation, nascent planetary systems are subject to FU Orionis outbursts that heat a substantial part of the disc. This causes water ice in the affected part of the disc to sublimate as the ice line moves outwards to several to tens of astronomical units. In this paper, we investigate how the subsequent cooling of the disc impacts the particle sizes. We calculate the resulting particle sizes in a disc model with cooling times between 100 and 1000 yr, corresponding to typical FU Orionis outbursts. As the disc cools and the ice line retreats inwards, water vapour forms icy mantles on existing silicate particles. This process is called heterogeneous nucleation. The nucleation rate per surface area of silicate substrate strongly depends on the degree of super-saturation of the water vapour in the gas. Fast cooling results in high super-saturation levels, high nucleation rates, and limited condensation growth because the main ice budget is spent in the nucleation. Slow cooling, on the other hand, leads to rare ice nucleation and efficient growth of ice-nucleated particles by subsequent condensation. We demonstrate that close to the quiescent ice line, pebbles with a size of about centimetres to decimetres form by this process. The largest of these are expected to undergo cracking collisions. However, their Stokes numbers still reach values that are high enough to potentially trigger planetesimal formation by the streaming instability if the background turbulence is weak. Stellar outbursts may thus promote planetesimal formation around the water ice line in protoplanetary discs.</p>}},
  author       = {{Ros, Katrin and Johansen, Anders}},
  issn         = {{0004-6361}},
  keywords     = {{Planet-disk interactions; Planets and satellites: formation; Protoplanetary disks}},
  language     = {{eng}},
  month        = {{06}},
  publisher    = {{EDP Sciences}},
  series       = {{Astronomy and Astrophysics}},
  title        = {{Fast formation of large ice pebbles after FU Orionis outbursts}},
  url          = {{http://dx.doi.org/10.1051/0004-6361/202348101}},
  doi          = {{10.1051/0004-6361/202348101}},
  volume       = {{686}},
  year         = {{2024}},
}