Diffusive Tidal Evolution for Migrating hot Jupiters

TL;DR

This paper proposes a diffusive tidal evolution mechanism involving f-mode excitation in highly eccentric Jovian planets, explaining rapid migration and circularization of hot Jupiters without explicit dissipation.

Contribution

It introduces a new diffusive tidal process driven by f-mode growth, providing a novel explanation for hot Jupiter formation via high-eccentricity migration.

Findings

F-mode can grow to large amplitudes if energy gain per orbit exceeds 10^-5 of orbital energy.

The mechanism can rapidly circularize orbits within ~10^4 years.

Explains the observed scarcity of super-eccentric Jovian planets.

Abstract

I consider a Jovian planet on a highly eccentric orbit around its host star, a situation produced by secular interactions with its planetary or stellar companions. The tidal interactions at every periastron passage exchange energy between the orbit and the planet's degree-2 fundamental-mode. Starting from zero energy, the f-mode can diffusively grow to large amplitudes if its one-kick energy gain > 10^-5 of the orbital energy. This requires a pericentre distance of < 4 tidal radii (or 1.6 Roche radii). If the f-mode has a non-negligible initial energy, diffusive evolution can occur at a lower threshold. The first effect can stall the secular migration as the f-mode can absorb orbital energy and decouple the planet from its secular perturbers, parking all migrating jupiters safely outside the zone of tidal disruption. The second effect leads to rapid orbit circularization as it allows an excited f-mode to continuously absorb orbital energy as the orbit eccentricity decreases. So without any explicit dissipation, other than the fact that the f-mode will damp nonlinearly when its amplitude reaches unity, the planet can be transported from a few AU to ~ 0.2 AU in ~ 10^4 yrs. Such a rapid circularization is equivalent to a dissipation factor Q ~ 1, and it explains the observed deficit of super-eccentric Jovian planets. Lastly, the repeated f-mode breaking likely deposit energy and angular momentum in the outer envelope, and avoid thermally ablating the planet. Overall, this work boosts the case for forming hot Jupiters through high-eccentricity secular migration.