Predicting the Configuration of Planetary System: KOI-152 Observed by Kepler

TL;DR

This study models the formation of the KOI-152 planetary system, emphasizing the role of migration halting mechanisms and disk properties in shaping its near-resonant configuration.

Contribution

It introduces a detailed simulation approach considering migration dead zones and magnetic truncation, highlighting factors influencing planetary system architecture.

Findings

Slow type I migration favors KOI-152's configuration.

Planetary masses are estimated to be below 24 Earth masses.

Low stellar accretion rates or high magnetic fields support the system's formation.

Abstract

The recent Kepler discovery of KOI-152 reveals a system of three hot super-Earth candidates that are in or near a 4:2:1 mean motion resonance. It is unlikely that they formed in situ, the planets probably underwent orbital migration during the formation and evolution process. The small semimajor axes of the three planets suggest that migration stopped at the inner edge of the primordial gas disk. In this paper we focus on the influence of migration halting mechanisms, including migration "dead zones", and inner truncation by the stellar magnetic field. We show that the stellar accretion rate, stellar magnetic field and the speed of migration in the proto-planetary disk are the main factors affecting the final configuration of KOI-152. Our simulations suggest that three planets may be around a star with low star accretion rate or with high magnetic field. On the other hand, slow type I migration, which decreases to one tenth of the linear analysis results, favors forming the configuration of KOI-152. Under such formation scenario, the planets in the system are not massive enough to open gaps in the gas disk. The upper limit of the planetary masses are estimated to be about $15,~19$, and $24 M_\oplus$, respectively. Our results are also indicative of the near Laplacian configurations that are quite common in planetary systems.