Tidal Evolution of Close-in Planets

TL;DR

This paper investigates the tidal evolution of close-in exoplanets, showing that tidal dissipation significantly influences their orbital paths, potentially explaining observed eccentricities and misalignments, and revisiting previous claims about parameter evolution timescales.

Contribution

It provides a detailed analysis of tidal dissipation effects on close-in planets, highlighting two main evolutionary paths and revisiting prior assumptions about parameter evolution.

Findings

Most close-in planets experience orbital decay towards the Roche limit.

Two characteristic evolution paths depend on tidal dissipation efficiency.

Some systems could have had highly misaligned orbits in the past.

Abstract

Recent discoveries of several transiting planets with clearly non-zero eccentricities and some large inclinations started changing the simple picture of close-in planets having circular and well-aligned orbits. Two major scenarios to form such planets are planet migration in a disk, and planet--planet interactions combined with tidal dissipation. The former scenario can naturally produce a circular and low-obliquity orbit, while the latter implicitly assumes an initially highly eccentric and possibly high-obliquity orbit, which are then circularized and aligned via tidal dissipation. We investigate the tidal evolution of transiting planets on eccentric orbits. We show that the current and future orbital evolution of these systems is likely dominated by tidal dissipation, and not by a more distant companion. Although most of these close-in planets experience orbital decay all the way to the Roche limit, there are two characteristic evolution paths for them, depending on the relative efficiency of tidal dissipation inside the star and the planet. We point out that the current observations may be consistent with one of them. Our results suggest that at least some of the close-in planets with non-zero orbital eccentricity may have been formed by tidally circularizing an initially eccentric orbit. We also find that even when the stellar spin-orbit misalignment is observed to be small at present, some systems could have had a highly misaligned orbit in the past. Finally, we also re-examine the recent claim by Levrard et. al., who found that all orbital and spin parameters evolve on a similar timescale to orbital decay.