Tides in the high-eccentricity migration of hot Jupiters: Triggering diffusive growth by nonlinear mode interactions

TL;DR

This paper demonstrates that nonlinear mode interactions significantly promote diffusive growth of planetary f-modes, potentially accelerating hot Jupiter formation via high-eccentricity migration and aligning theoretical predictions with observations.

Contribution

It reveals that nonlinear mode interactions dominate phase shifts, lowering the energy threshold for diffusive growth and enhancing hot Jupiter formation rates.

Findings

Nonlinear interactions induce a dominant phase shift over tidal back-reaction.

The energy threshold for diffusive growth is reduced by about a factor of 5.

Enhanced diffusive growth could explain observed hot Jupiter populations.

Abstract

High eccentricity migration is a possible formation channel for hot Jupiters. However, in order for it to be consistent with the observed population of planets, tides must circularize the orbits in less than $\approx$ a Myr. A potential mechanism for such rapid circularization is the diffusive growth of the tidally driven planetary f-mode. Such growth occurs if the f-mode's phase at pericenter varies chaotically from one pericenter passage to the next. Previous studies focused on the variation of the orbital period due to tidal back-reaction on the orbit as the source of chaos. Here we show that nonlinear mode interactions can also be an important source. Specifically, we show that nonlinear interactions between a parent f-mode and daughter f-/p-modes induce an energy-dependent shift in the oscillation frequency of the parent. This frequency shift varies randomly from orbit to orbit because the parent's energy varies. As a result, the parent's phase at pericenter varies randomly, which we find can trigger it to grow diffusively. We show that the phase shift induced by nonlinear mode interactions in fact dominates the shift induced by tidal back-reaction and significantly lowers the one-kick energy threshold for diffusive growth by about a factor of 5 compared to the linear theory's prediction. Nonlinear interactions could thus enhance the formation rate of hot Jupiters through the high-eccentricity migration channel and potentially mitigate the discrepancy between the observed and predicted occurrence rates for close-in gas giants as compared to those further from the star.