Growth and evolution of satellites in a Jovian massive disc

Abstract The formation of satellite systems in circum-planetary discs is considered to be similar to the formation of rocky planets in a proto-planetary disc, especially super-Earths. Thus, it is possible to use systems with large satellites to test formation theories that are also applicable to ext...

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Bibliographic Details
Published in:Monthly notices of the Royal Astronomical Society 2018-03, Vol.475 (1), p.1347-1362
Main Authors: Moraes, R A, Kley, W, Vieira Neto, E
Format: Article
Language:English
Subjects:
Accretion disks
Aspect ratio
Callisto
Computer simulation
Damping
Dynamical systems
Embryos
Extrasolar planets
Galilean satellites
Ganymede
Gas density
Inclination
Jupiter
Jupiter satellites
Migration
Nebulae
Orbital resonances (celestial mechanics)
Planet formation
Terrestrial planets
Viscosity
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Summary:Abstract The formation of satellite systems in circum-planetary discs is considered to be similar to the formation of rocky planets in a proto-planetary disc, especially super-Earths. Thus, it is possible to use systems with large satellites to test formation theories that are also applicable to extrasolar planets. Furthermore, a better understanding of the origin of satellites might yield important information about the environment near the growing planet during the last stages of planet formation. In this work, we investigate the formation and migration of the Jovian satellites through N-body simulations. We simulated a massive, static, low-viscosity, circum-planetary disc in agreement with the minimum mass sub-nebula model prescriptions for its total mass. In hydrodynamic simulations, we found no signs of gaps, therefore type II migration is not expected. Hence, we used analytic prescriptions for type I migration, eccentricity and inclination damping, and performed N-body simulations with damping forces added. Detailed parameter studies showed that the number of final satellites is strong influenced by the initial distribution of embryos, the disc temperature, and the initial gas density profile. For steeper initial density profiles, it is possible to form systems with multiple satellites in resonance while a flatter profile favours the formation of satellites close to the region of the Galilean satellites. We show that the formation of massive satellites such as Ganymede and Callisto can be achieved for hotter discs with an aspect ratio of H/r ∼ 0.15 for which the ice line was located around 30RJ.
ISSN:0035-8711
1365-2966
DOI:10.1093/mnras/stx3268