Dynamical rearrangement of super-Earths during disk dispersal I. Outline of the magnetospheric rebound model

TL;DR

This paper introduces the magnetospheric rebound model, explaining how super-Earth pairs can escape mean motion resonances during disk dispersal, aligning theory with observed planetary configurations.

Contribution

It proposes a new mechanism where magnetospheric cavity expansion during disk dispersal causes orbital rearrangement of super-Earths, resolving discrepancies with traditional migration theory.

Findings

Planets can escape resonances during disk dispersal due to cavity expansion.

The final orbital configuration depends on planet mass ratio and magnetic field strength.

Magnetospheric rebound can explain observed period ratios of super-Earths.

Abstract

The Kepler mission has discovered that multiple close-in super-Earth planets are common around solar-type stars, but their period ratios do not show strong pile-ups near mean motion resonances (MMRs). One scenario is that super-Earths form in a gas-rich disk, and they interact gravitationally with the surrounding gas, inducing their orbital migration. Disk migration theory predicts, however, that planets would end up at resonant orbits due to their differential migration speed. Motivated by the discrepancy between observation and theory, we seek for a mechanism that moves planets out of resonances. We examine the orbital evolution of planet pairs near the magnetospheric cavity during the gas disk dispersal phase. Our study determines the conditions under which planets can escape resonances. We perform two-planet N-body simulations, varying the planet masses, stellar magnetic field strengths, disk accretion rates and gas disk depletion timescales. As planets migrate outward with the expanding magnetospheric cavity, their dynamical configurations can be rearranged. Migration of planets is substantial (minor) in a massive (light) disk. When the outer planet is more massive than the inner planet, the period ratio of two planets increases through outward migration. On the other hand, when the inner planet is more massive, the final period ratio tends to remain similar to the initial one. Larger stellar magnetic field strengths result in planets stopping their migration at longer periods. We highlight \textit{magnetospheric rebound} as an important ingredient able to reconcile disk migration theory with observations. Even when planets are trapped into MMR during the early gas-rich stage, subsequent cavity expansion would induce substantial changes to their orbits, moving them out of resonance.