Impact of Planetary Parameters on Water Clouds Microphysics

TL;DR

This study investigates how planetary parameters influence water cloud microphysics on exoplanets, highlighting the importance of accurate cloud modeling for understanding habitability and interpreting future observations.

Contribution

It demonstrates the dependence of cloud microphysics and radiative effects on planetary and aerosol properties using a 1D microphysical model, informing better GCM schemes.

Findings

Surface pressure and stellar flux significantly impact cloud radiative effects.

Gravity and aerosol number density influence cloud formation processes.

Microphysical processes are sensitive to planetary parameters, affecting climate predictions.

Abstract

Potentially habitable exoplanets are targets of great interest for the James Webb Space Telescope and upcoming mission concepts such as the Habitable Worlds Observatory. Clouds strongly affect climate and habitability, but predicting their properties is difficult. In Global Climate Models (GCMs), especially those aiming at simulating Earth, cloud microphysics is often crudely approximated by assuming that all cloud particles have a single, constant size or a prescribed size distribution and that all clouds in a grid cell are identical. For exoplanets that range over a large phase space of planetary properties, this method could result in large errors. In this work, our goal is to determine how cloud microphysics on terrestrial exoplanets, whose condensable is mainly water vapor, depend on aerosol properties and planetary parameters such as surface pressure, surface gravity, and incident stellar radiation. We use the Community Aerosol and Radiation Model for Atmospheres as a 1D microphysical model to simulate the formation and evolution of clouds including the processes of nucleation, condensation, evaporation, coagulation, and vertical transfer. In these 1D idealized experiments, we find that the parameters that determine the macrophysical thermal structure of the atmospheres, including surface pressure and stellar flux, impact cloud radiative effect (CRE) most significantly. Parameters such as gravity and number density of aerosols working as cloud condensation nuclei affect the microphysical processes of cloud formation, including activation and vertical transfer. They also have a significant, though weaker effect on CRE. This work motivates the development of more accurate GCM cloud schemes and should aid in the interpretation of future observations.