On the evolution of mean motion resonances through stochastic forcing: Fast and slow libration modes and the origin of HD128311

TL;DR

This paper investigates how stochastic forcing from disk turbulence affects the evolution of mean motion resonances in planetary systems, explaining the observed configuration of HD128311 through analytic and numerical models.

Contribution

It introduces a comprehensive analytic and numerical framework to study the impact of stochastic forcing on libration modes in resonant planetary systems, with application to HD128311.

Findings

Large stochastic forcing destabilizes systems quickly.

Slow libration mode converts to circulation more easily.

Stochastic forcing can explain the configuration of HD128311.

Abstract

Aims. We clarify the response of extrasolar planetary systems in a 2:1 mean motion commensurability with masses ranging from the super Jovian range to the terrestrial range to stochastic forcing that could result from protoplanetary disk turbulence. The behaviour of the different libration modes for a wide range of system parameters and stochastic forcing magnitudes is investigated. The growth of libration amplitudes is parameterized as a function of the relevant physical parameters. The results are applied to provide an explanation of the configuration of the HD128311 system. Methods. We first develop an analytic model from first principles without making the assumption that both eccentricities are small. We also perform numerical N-body simulations with additional stochastic forcing terms to represent the effects of putative disk turbulence. Results. Systems are quickly destabilized by large magnitudes of stochastic forcing but some stability is imparted should systems undergo a net orbital migration. The slow mode, which mostly corresponds to motion of the angle between the apsidal lines of the two planets, is converted to circulation more readily than the fast mode which is associated with oscillations of the semi-major axes. This mode is also vulnerable to the attainment of small eccentricities which causes oscillations between periods of libration and circulation. Conclusions. Stochastic forcing due to disk turbulence may have played a role in shaping the configurations of observed systems in mean motion resonance. It naturally provides a mechanism for accounting for the HD128311 system.