The Diversity of Planetary Systems Architectures: Contrasting Theory with Observations

YAMILA MIGUEL; OCTAVIO MIGUEL GUILERA; ADRIÁN BRUNINI

MONTHLY NOTICES OF THE ROYAL ASTRONOMICAL SOCIETY

WILEY-BLACKWELL PUBLISHING, INC

Lugar: Londres; Año: 2011 vol. 417 p. 314 - 332

0035-8711

In order to explain the observed diversity of planetary systems architectures and relate this primordial diversity with the initial properties of the disc where they were born, we develop a semi-analytical model for computing planetary system formation.The model is based on the core instability model for the gas accretion of the embryos and the oligarchic growth regime for the accretion of the solid cores. Two regimes of planetary migration are also included. With this model, we consider different initial conditions based on recent results in protoplanetary discs observations, to generate a variety of planetary systems. These systems are analyzed statistically, exploring the importance of several factors that define the planetary systems birth environment. We explore the relevance of the mass and size of the disc, metallicity, mass of the central star and time-scale of gaseous disc dissipation, in defining the architecture of the planetary system. We also test different values of some key parameters of our model, to find out which factors best reproduce the diverse sample of observed planetary systems. We assume different migration rates and initial disc profiles, in the context of a surface density profile motivated by similarity solutions. According to this, and based on recent protoplanetary discs observational data, we predict which systems are the most common in the solar neighbourhood. We intend to unveil, whether our Solar System is a rarity or more planetary systems like our own are expected to be found in the near future. We also analyze which is the more favourable environment for theformation of habitable planets. Our results show that planetary systems with only terrestrial planets are the most common, being the only planetary systems formed when considering low metallicity discs and which also represent the best environment for the developing of rocky, potentially habitable planets.We also found that planetary systems like our own are not rare in the solar neighbourhood, being its formation favoured in massive discs where there is not a large accumulation of solids in the inner region of the disc. Regarding the planetary systems that harbor hot and warm Jupiter planets, we found that this systems are born in very massive, metal-rich discs. Also a fast migration rate is required in order to form these systems. According to our results, most of the hot and warm Jupiter systems are composed by only one giant planet, which is also a tendency of the current observational data.