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Disc population synthesis : Decrease in the solid mass reservoir through pebble drift

Appelgren, J. LU ; Lambrechts, M. LU and Van Der Marel, N. (2023) In Astronomy and Astrophysics 673.
Abstract

Surveys of star-forming regions reveal that the dust mass of protoplanetary discs decreases by several orders of magnitude on timescales of a few million years. This decrease in the mass budget of solids is likely due to the radial drift of millimetre (mm) sized solids, called pebbles, induced by gas drag. However, quantifying the evolution of this dust component in young stellar clusters is difficult due to the inherent large spread in stellar masses and formation times. Therefore, we aim to model the collective evolution of a cluster to investigate the effectiveness of radial drift in clearing the discs of mm-sized particles. We use a protoplanetary disc model that provides a numerical solution for the disc formation, as well as the... (More)

Surveys of star-forming regions reveal that the dust mass of protoplanetary discs decreases by several orders of magnitude on timescales of a few million years. This decrease in the mass budget of solids is likely due to the radial drift of millimetre (mm) sized solids, called pebbles, induced by gas drag. However, quantifying the evolution of this dust component in young stellar clusters is difficult due to the inherent large spread in stellar masses and formation times. Therefore, we aim to model the collective evolution of a cluster to investigate the effectiveness of radial drift in clearing the discs of mm-sized particles. We use a protoplanetary disc model that provides a numerical solution for the disc formation, as well as the viscous evolution and photoevaporative clearing of the gas component, while also including the drift of particles limited in size by fragmentation. We find that discs are born with dust masses between 50 M· and 1000 M·, for stars with masses, respectively, between 0.1 M· and 1 M·. The majority of this initial dust reservoir is typically lost through drift before photoevaporation opens a gap in the gas disc for models both with and without strong X-ray-driven mass-loss rates. We conclude that the decrease in time of the mass locked in fragmentation-limited pebbles is consistent with the evolution of dust masses and ages inferred from nearby star-forming regions, when assuming viscous evolution rates corresponding to mean gas disc lifetimes between 3 Myr and 8 Myr.

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author
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organization
publishing date
type
Contribution to journal
publication status
published
subject
keywords
Methods: numerical, Planets and satellites: formation, Protoplanetary disks
in
Astronomy and Astrophysics
volume
673
article number
A139
publisher
EDP Sciences
external identifiers
  • scopus:85161019611
ISSN
0004-6361
DOI
10.1051/0004-6361/202245252
language
English
LU publication?
yes
id
36e26d4f-a29c-4618-b71a-c528b055263f
date added to LUP
2023-08-22 08:58:27
date last changed
2024-02-03 16:44:14
@article{36e26d4f-a29c-4618-b71a-c528b055263f,
  abstract     = {{<p>Surveys of star-forming regions reveal that the dust mass of protoplanetary discs decreases by several orders of magnitude on timescales of a few million years. This decrease in the mass budget of solids is likely due to the radial drift of millimetre (mm) sized solids, called pebbles, induced by gas drag. However, quantifying the evolution of this dust component in young stellar clusters is difficult due to the inherent large spread in stellar masses and formation times. Therefore, we aim to model the collective evolution of a cluster to investigate the effectiveness of radial drift in clearing the discs of mm-sized particles. We use a protoplanetary disc model that provides a numerical solution for the disc formation, as well as the viscous evolution and photoevaporative clearing of the gas component, while also including the drift of particles limited in size by fragmentation. We find that discs are born with dust masses between 50 M· and 1000 M·, for stars with masses, respectively, between 0.1 M· and 1 M·. The majority of this initial dust reservoir is typically lost through drift before photoevaporation opens a gap in the gas disc for models both with and without strong X-ray-driven mass-loss rates. We conclude that the decrease in time of the mass locked in fragmentation-limited pebbles is consistent with the evolution of dust masses and ages inferred from nearby star-forming regions, when assuming viscous evolution rates corresponding to mean gas disc lifetimes between 3 Myr and 8 Myr.</p>}},
  author       = {{Appelgren, J. and Lambrechts, M. and Van Der Marel, N.}},
  issn         = {{0004-6361}},
  keywords     = {{Methods: numerical; Planets and satellites: formation; Protoplanetary disks}},
  language     = {{eng}},
  publisher    = {{EDP Sciences}},
  series       = {{Astronomy and Astrophysics}},
  title        = {{Disc population synthesis : Decrease in the solid mass reservoir through pebble drift}},
  url          = {{http://dx.doi.org/10.1051/0004-6361/202245252}},
  doi          = {{10.1051/0004-6361/202245252}},
  volume       = {{673}},
  year         = {{2023}},
}