Formation of moon systems around giant planets: Capture and ablation of planetesimals as foundation for a pebble accretion scenario

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Formation of moon systems around giant planets : Capture and ablation of planetesimals as foundation for a pebble accretion scenario. / Ronnet, T.; Johansen, A.

In: Astronomy and Astrophysics, Vol. 633, A93, 2020.

Research output: Contribution to journalJournal articleResearchpeer-review

Harvard

Ronnet, T & Johansen, A 2020, 'Formation of moon systems around giant planets: Capture and ablation of planetesimals as foundation for a pebble accretion scenario', Astronomy and Astrophysics, vol. 633, A93. https://doi.org/10.1051/0004-6361/201936804

APA

Ronnet, T., & Johansen, A. (2020). Formation of moon systems around giant planets: Capture and ablation of planetesimals as foundation for a pebble accretion scenario. Astronomy and Astrophysics, 633, [A93]. https://doi.org/10.1051/0004-6361/201936804

Vancouver

Ronnet T, Johansen A. Formation of moon systems around giant planets: Capture and ablation of planetesimals as foundation for a pebble accretion scenario. Astronomy and Astrophysics. 2020;633. A93. https://doi.org/10.1051/0004-6361/201936804

Author

Ronnet, T. ; Johansen, A. / Formation of moon systems around giant planets : Capture and ablation of planetesimals as foundation for a pebble accretion scenario. In: Astronomy and Astrophysics. 2020 ; Vol. 633.

Bibtex

@article{ec4da81e972b4ef496773ca8981239be,
title = "Formation of moon systems around giant planets: Capture and ablation of planetesimals as foundation for a pebble accretion scenario",
abstract = "The four major satellites of Jupiter, known as the Galilean moons, and Saturn's most massive satellite, Titan, are believed to have formed in a predominantly gaseous circum-planetary disk during the last stages of formation of their parent planet. Pebbles from the protoplanetary disk are blocked from flowing into the circumplanetary disk by the positive pressure gradient at the outer edge of the planetary gap, so the gas drag assisted capture of planetesimals should be the main contributor to the delivery of solids onto circum-planetary disks. However, a consistent framework for the subsequent accretion of the moons remains to be built. Here, we use numerical integrations to show that most planetesimals that are captured within a circum-planetary disk are strongly ablated due to the frictional heating they experience, thus supplying the disk with small dust grains, whereas only a small fraction {"}survives{"}their capture. We then constructed a simple model of a circum-planetary disk supplied by ablation, where the flux of solids through the disk is at equilibrium with the ablation supply rate, and we investigate the formation of moons in such disks. We show that the growth of satellites is mainly driven by accretion of the pebbles that coagulate from the ablated material. The pebble-accreting protosatellites rapidly migrate inward and pile up in resonant chains at the inner edge of the circum-planetary disk. We propose that dynamical instabilities in these resonant chains are at the origin of the different architectures of Jupiter's and Saturn's moon systems. The assembly of moon systems through pebble accretion can therefore be seen as a down-scaled manifestation of the same process that forms systems of super-Earths and terrestrial-mass planets around solar-type stars and M-dwarfs. ",
keywords = "formation, Galilean moons, gaseous planets, individual, Planets and satellites, Titan",
author = "T. Ronnet and A. Johansen",
note = "Publisher Copyright: {\textcopyright} ESO 2020.",
year = "2020",
doi = "10.1051/0004-6361/201936804",
language = "English",
volume = "633",
journal = "Astronomy & Astrophysics",
issn = "0004-6361",
publisher = "E D P Sciences",

}

RIS

TY - JOUR

T1 - Formation of moon systems around giant planets

T2 - Capture and ablation of planetesimals as foundation for a pebble accretion scenario

AU - Ronnet, T.

AU - Johansen, A.

N1 - Publisher Copyright: © ESO 2020.

PY - 2020

Y1 - 2020

N2 - The four major satellites of Jupiter, known as the Galilean moons, and Saturn's most massive satellite, Titan, are believed to have formed in a predominantly gaseous circum-planetary disk during the last stages of formation of their parent planet. Pebbles from the protoplanetary disk are blocked from flowing into the circumplanetary disk by the positive pressure gradient at the outer edge of the planetary gap, so the gas drag assisted capture of planetesimals should be the main contributor to the delivery of solids onto circum-planetary disks. However, a consistent framework for the subsequent accretion of the moons remains to be built. Here, we use numerical integrations to show that most planetesimals that are captured within a circum-planetary disk are strongly ablated due to the frictional heating they experience, thus supplying the disk with small dust grains, whereas only a small fraction "survives"their capture. We then constructed a simple model of a circum-planetary disk supplied by ablation, where the flux of solids through the disk is at equilibrium with the ablation supply rate, and we investigate the formation of moons in such disks. We show that the growth of satellites is mainly driven by accretion of the pebbles that coagulate from the ablated material. The pebble-accreting protosatellites rapidly migrate inward and pile up in resonant chains at the inner edge of the circum-planetary disk. We propose that dynamical instabilities in these resonant chains are at the origin of the different architectures of Jupiter's and Saturn's moon systems. The assembly of moon systems through pebble accretion can therefore be seen as a down-scaled manifestation of the same process that forms systems of super-Earths and terrestrial-mass planets around solar-type stars and M-dwarfs.

AB - The four major satellites of Jupiter, known as the Galilean moons, and Saturn's most massive satellite, Titan, are believed to have formed in a predominantly gaseous circum-planetary disk during the last stages of formation of their parent planet. Pebbles from the protoplanetary disk are blocked from flowing into the circumplanetary disk by the positive pressure gradient at the outer edge of the planetary gap, so the gas drag assisted capture of planetesimals should be the main contributor to the delivery of solids onto circum-planetary disks. However, a consistent framework for the subsequent accretion of the moons remains to be built. Here, we use numerical integrations to show that most planetesimals that are captured within a circum-planetary disk are strongly ablated due to the frictional heating they experience, thus supplying the disk with small dust grains, whereas only a small fraction "survives"their capture. We then constructed a simple model of a circum-planetary disk supplied by ablation, where the flux of solids through the disk is at equilibrium with the ablation supply rate, and we investigate the formation of moons in such disks. We show that the growth of satellites is mainly driven by accretion of the pebbles that coagulate from the ablated material. The pebble-accreting protosatellites rapidly migrate inward and pile up in resonant chains at the inner edge of the circum-planetary disk. We propose that dynamical instabilities in these resonant chains are at the origin of the different architectures of Jupiter's and Saturn's moon systems. The assembly of moon systems through pebble accretion can therefore be seen as a down-scaled manifestation of the same process that forms systems of super-Earths and terrestrial-mass planets around solar-type stars and M-dwarfs.

KW - formation

KW - Galilean moons

KW - gaseous planets

KW - individual

KW - Planets and satellites

KW - Titan

U2 - 10.1051/0004-6361/201936804

DO - 10.1051/0004-6361/201936804

M3 - Journal article

AN - SCOPUS:85085282215

VL - 633

JO - Astronomy & Astrophysics

JF - Astronomy & Astrophysics

SN - 0004-6361

M1 - A93

ER -

ID: 327033835