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3D Convection-resolving Model of Temperate, Tidally Locked Exoplanets

Maxence Lefèvre, Martin Turbet, Raymond Pierrehumbert

2021The Astrophysical Journal27 citationsDOIOpen Access PDF

Abstract

Abstract A large fraction of known terrestrial-size exoplanets located in the habitable zone of M-dwarfs are expected to be tidally locked. Numerous efforts have been conducted to study the climate of such planets, using in particular 3D global climate models (GCMs). One of the biggest challenges in simulating such an extreme environment is to properly represent the effects of sub-grid convection. Most GCMs use either a simplistic convective-adjustment parameterization or sophisticated (e.g., mass flux scheme) Earth-tuned parameterizations. One way to improve the representation of convection is to study convection using numerical convection-resolving models (CRMs), with a fine spatial resolution. In this study, we developed a CRM coupling the non-hydrostatic dynamical core Advanced Research Weather-Weather Research and Forecast model with the radiative transfer and cloud/precipitation models of the Laboratoire de Météorologie Dynamique generic climate model to study convection and clouds on tidally locked planets, with a focus on Proxima b. Simulations were performed for a set of three surface temperatures (corresponding to three different incident fluxes) and two rotation rates, assuming an Earth-like atmosphere. The main result of our study is that while we recover the prediction of GCMs that (low-altitude) cloud albedo increases with increasing stellar flux, the cloud feedback is much weaker due to transient aggregation of convection leading to low partial cloud cover.

Topics & Concepts

PhysicsExoplanetConvectionRadiative transferAlbedo (alchemy)PlanetCircumstellar habitable zoneTidal lockingClimate modelFlux (metallurgy)Cloud computingAstrophysicsStarsAtmospheric modelConvection zonePlanetary habitabilityAtmospheric radiative transfer codesCoupling (piping)Rotation (mathematics)Cloud physicsMeteorologyAtmospheric modelsAtmosphere (unit)Atmospheric convectionFocus (optics)Monochromatic colorAstronomyAtmospheric sciencesUnified ModelTransient (computer programming)Stellar evolutionHot JupiterCore (optical fiber)Numerical modelsStellar, planetary, and galactic studiesSolar and Space Plasma DynamicsAdaptive optics and wavefront sensing
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