Affiliation:
1. LATMOS/IPSL Sorbonne Université UVSQ Université Paris‐Saclay CNRS Paris France
2. Laboratoire de Météorologie Dynamique/Institut Pierre Simon Laplace (LMD/IPSL) Sorbonne Université Centre National de La Recherche Scientifique (CNRS) École Polytechnique École Normale Supérieure (ENS) Paris France
3. LESIA Observatoire de Paris Université PSL CNRS Sorbonne Université Université Paris Cité Meudon France
Abstract
AbstractMartian CO2 ice clouds are intriguing features, representing a rare occurrence of atmospheric condensation of a major component. These clouds play a crucial role due to their radiative properties, interactions with surface, and coupling with microphysical cycles of aerosols. Observations have been limited, prompting modeling studies to understand their formation and dynamics. Here, we present the first high‐resolution 3D simulations of CO2 ice clouds using a Large‐Eddy Simulation (LES) model incorporating CO2 microphysics. We investigate cloud formation in idealized temperature perturbations in the polar night. A reference simulation with a −2K perturbation demonstrates that the formed CO2 ice cloud possesses a convective potential, leading to its ascent in the troposphere. We determine the timescales and orders of magnitude of various phenomena involved in the lifecycle of a CO2 ice cloud. Sensitivity tests show that convection can be inhibited or intensified by the thermodynamic and microphysical conditions of the simulated environment.
Funder
Agence Nationale de la Recherche
Publisher
American Geophysical Union (AGU)