3D modeling of GJ1214b's atmosphere: formation of inhomogeneous high clouds and observational implications

TL;DR

This study uses 3D atmospheric modeling to explore cloud formation, circulation, and observational signatures on GJ1214b, revealing inhomogeneous high clouds, thermal inversions, and implications for future JWST observations.

Contribution

It presents the first 3D GCM simulations of GJ1214b's cloudy atmosphere including radiative effects, showing cloud transport, thermal inversions, and observational predictions.

Findings

Clouds increase planetary albedo to 0.4-0.6.

Thermal inversions form above 10 mbar due to ZnS clouds.

Phase curves depend strongly on metallicity, weakly on clouds.

Abstract

The warm sub-Neptune GJ1214b has a featureless transit spectrum which may be due to the presence of high and thick clouds or haze. Here, we simulate the atmosphere of GJ1214b with a 3D General Circulation Model for cloudy hydrogen-dominated atmospheres, including cloud radiative effects. We show that the atmospheric circulation is strong enough to transport micrometric cloud particles to the upper atmosphere and generally leads to a minimum of cloud at the equator. By scattering stellar light, clouds increase the planetary albedo to 0.4-0.6 and cool the atmosphere below 1 mbar. However, the heating by ZnS clouds leads to the formation of a stratospheric thermal inversion above 10 mbar, with temperatures potentially high enough on the dayside to evaporate KCl clouds. We show that flat transit spectra consistent with HST observations are possible if cloud particle radii are around 0.5 micron, and that such clouds should be optically thin at wavelengths > 3 microns. Using simulated cloudy atmospheres that fit the observed spectra we generate transit, emission and reflection spectra and phase curves for GJ1214b. We show that a stratospheric thermal inversion would be readily accessible in near and mid-infrared atmospheric spectral windows. We find that the amplitude of the thermal phase curves is strongly dependent on metallicity, but only slightly impacted by clouds. Our results suggest that primary and secondary eclipses and phase curves observed by the James Webb Space Telescope in the near to mid-infrared should provide strong constraints on the nature of GJ1214b's atmosphere and clouds.