Atmospheric dynamics of Earth-like tidally locked aquaplanets

TL;DR

This study uses simulations to explore how Earth-like tidally locked planets' atmospheres behave under different rotation rates, revealing the influence of rotation on climate patterns and heat distribution.

Contribution

It provides new insights into atmospheric circulation and climate dynamics of tidally locked exoplanets with varying rotation periods, expanding understanding beyond previous models.

Findings

Heat transport reduces night side temperature extremes.

Rapid rotation leads to zonal, rotational winds; slow rotation results in divergent flows.

Temperature variations are more pronounced in rapidly rotating atmospheres.

Abstract

We present simulations of atmospheres of Earth-like aquaplanets that are tidally locked to their star, that is, planets whose orbital period is equal to the rotation period about their spin axis, so that one side always faces the star and the other side is always dark. As extreme cases illustrating the effects of slow and rapid rotation, we consider planets with rotation periods equal to one current Earth year and one current Earth day. The dynamics responsible for the surface climate (e.g., winds, temperature, precipitation) and the general circulation of the atmosphere are discussed in light of existing theories of atmospheric circulations. For example, as expected from the increasing importance of Coriolis accelerations relative to inertial accelerations as the rotation rate increases, the winds are approximately isotropic and divergent at leading order in the slowly rotating atmosphere but are predominantly zonal and rotational in the rapidly rotating atmosphere. Free-atmospheric horizontal temperature variations in the slowly rotating atmosphere are generally weaker than in the rapidly rotating atmosphere. Interestingly, the surface temperature on the night side of the planets does not fall below ~240 K in either the rapidly or slowly rotating atmosphere; that is, heat transport from the day side to the night side of the planets efficiently reduces temperature contrasts in either case. Rotational waves shape the distribution of winds, temperature, and precipitation in the rapidly rotating atmosphere; in the slowly rotating atmosphere, these distributions are controlled by simpler divergent circulations. The results are of interest in the study of tidally locked terrestrial exoplanets and as illustrations of how planetary rotation and the insolation distribution shape climate.