Atmospheric tides and their consequences on the rotational dynamics of terrestrial planets

TL;DR

This paper develops an ab initio model of atmospheric tides on terrestrial planets, analyzing their impact on planetary rotation states, especially for Venus-like planets, by incorporating complex atmospheric physics often neglected in simpler models.

Contribution

It introduces a new analytical model of atmospheric tides based on Earth's theory, accounting for stratification and internal structure effects, to better predict planetary rotation states.

Findings

Stratification significantly influences tidal torque strength.

Convective atmospheres exhibit stronger tidal torques than stable ones.

The model predicts non-synchronized rotation states for Venus-like planets.

Abstract

Atmospheric tides can have a strong impact on the rotational dynamics of planets. They are of most importance for terrestrial planets located in the habitable zone of their host star, where their competition with solid tides is likely to drive the body towards non-synchronized rotation states of equilibrium, as observed in the case of Venus. Contrary to other planetary layers, the atmosphere is sensitive to both gravitational and thermal forcings, through a complex dynamical coupling involving the effects of Coriolis acceleration and characteristics of the atmospheric structure. These key physics are usually not taken into account in modelings used to compute the evolution of planetary systems, where tides are described with parametrised prescriptions. In this work, we present a new ab initio modeling of atmospheric tides adapting the theory of the Earth's atmospheric tides (Chapman & Lindzen 1970) to other terrestrial planets. We derive analytic expressions of the tidal torque, as a function of the tidal frequency and parameters characterizing the internal structure (e.g. the Brunt-V\"ais\"al\"a frequency, the radiative frequency, the pressure heigh scale). We show that stratification plays a key role, the tidal torque being strong in the case of convective atmospheres (i.e. with a neutral stratification) and weak in case of atmosphere convectively stable. In a second step, the model is used to determine the non-synchronized rotation states of equilibrium of Venus-like planets as functions of the physical parameters of the system. These results are detailed in Auclair-Desrotour et al. (2017a) and Auclair-Desrotour et al. (2017b).