Atmospheric circulation of brown dwarfs and directly imaged exoplanets driven by cloud radiative feedback: global and equatorial dynamics

TL;DR

This study investigates the global atmospheric circulation of brown dwarfs and exoplanets driven by cloud radiative feedback, revealing diverse wave patterns, jet formations, and variability effects that align with observations.

Contribution

It extends previous local models to global simulations, demonstrating how dissipation and rotation influence circulation patterns, wave dynamics, and observable variability.

Findings

Mid-to-high latitudes dominated by vortices

Low latitudes feature large-scale zonal waves

Equatorial waves impact lightcurve variability

Abstract

Brown dwarfs and directly imaged exoplanets exhibit observational evidence for active atmospheric circulation, raising critical questions about mechanisms driving the circulation, its fundamental nature, and time variability. Our previous work demonstrated the crucial role of cloud radiative feedback on driving a vigorous atmospheric circulation using local models that assume a Cartesian geometry and constant Coriolis parameters. In this study, we explore the properties of the global dynamics. We show that, under relatively strong dissipation in the bottom layers of the model, horizontally isotropic vortices are prevalent at mid-to-high latitudes while large-scale zonally propagating waves are dominant at low latitudes near the observable layers. The equatorial waves have both eastward and westward phase speeds, and the eastward components with typical speeds of a few hundred m/s usually dominate the equatorial time variability. Lightcurves of the global simulations show variability with amplitudes from 0.5 percent to a few percent depending on the rotation period and viewing angle. The time evolution of simulated lightcurves is critically affected by the equatorial waves, showing wave beating effects and differences in the lightcurve periodicity to the intrinsic rotation period. The vertical extent of clouds is the largest at the equator and decreases poleward due to the increasing influence of rotation with increasing latitude. Under weaker bottom dissipation, strong and broad zonal jets develop and modify wave propagation and lightcurve variability. Our modeling results help to explain the puzzling time evolution of observed lightcurves, a slightly shorter period of variability in IR than in radio wavelengths, and the viewing angle dependence of variability amplitude and IR colors.