Cloud-convection feedback in brown dwarfs atmosphere

Maxence Lefèvre; Xianyu Tan; Elspeth Lee; Raymond Pierrehumbert

doi:https://doi.org/10.5194/epsc2021-675

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EPSC Abstracts

Vol. 15, EPSC2021-675, 2021

https://doi.org/10.5194/epsc2021-675

European Planetary Science Congress 2021

© Author(s) 2021. This work is distributed under
the Creative Commons Attribution 4.0 License.

Cloud-convection feedback in brown dwarfs atmosphere

Maxence Lefèvre¹, Xianyu Tan¹, Elspeth Lee², and Raymond Pierrehumbert¹

Maxence Lefèvre et al.

¹University of Oxford, AOPP, Oxford, United Kingdom of Great Britain – England, Scotland, Wales (maxence.lefevre@physics.ox.ac.uk)
²University of Bern, Center for Space and Habitability, Switzerland

1. Introduction
Brown dwarfs are object between giant planets and star in term of mass, numerous observations suggest active meteorology. A near-infrared brightness variability is observed among L and T dwarfs. Several atmospheric dynamics have been proposed, but the mechanisms remain unclear. Clouds could also play an important role in shaping the thermal structure and spectral properties of these atmospheres via their opacity. In this study we propose to use a 3D convection resolving model couple to a grey-band radiative transfer and to a microphysical to study radiative cloud feedback over a large set of temperature, cloud composition and metallicity. The mechanism discussed in this study could play a role in the observed flux variability in brown dwarfs and is also applicable for directly imaged extrasolar giant planets.

2. Model
To study these mechanisms, the 3D non-hydrostatic dynamical CM1 is used coupled to a grey band radiative transfer [1]. An idealized cloud microphysical model was added, considering MgSiO₃ , Fe, Al₂O₃ , CaTiO₃ , Cr and MnS particles [3, 4, 5]. Particle settling is included. The effect of metallicity is taken into account. The clouds are radiatively active using Rosseland mean opacities. The cloud particles are considered spherical following a gaussian size distribution, with radius between 0.01 and 100 μm. The density of cloud particle is a free parameter. The model is initialized using temperature profile from a 1D model [2].

Figure 1: Initial vertical temperature profile (solid line) and condensation profile for the considered clouds (dotted line).

3. Results
The model shows that the convective layer height increases in function of the temperature (Fig 2). An estimate of the vertical mixing is determined. With the inclusion of radiative property of the clouds, some feedback is observed. MgSiO₃ , Fe and Al₂O₃ clouds tend to expend the convective layer altitude. This feedback is most visible at high temperature and depends on the clouds particle size. CaTiO₃ , Cr and MnS have very low impact on the convective layer, due to a thin cloud layer and a low abundance.

Figure 2: Vertical profile of the mean potential temperature (K) for the different temperature cases considerate without clouds.

References
[1] Freedman, R. S., et al. The Astrophysical Journal SupplementSeries, 214(2):25. 2014.
[2] Tan, X. and Showman, A. P. The Astrophysical Journal, 874(2):111. 2019.
[3] Visscher, C., et al. The Astrophysical Journal, 716(2):1060–1075. 2010.
[4] Wakeford, H. R., et al. Monthly Notices of the Royal Astronomical Society, 464(4):4247–4254. 2014.
[5] Morley, C. V., et al. The Astrophysical Journal, 756(2):172. 2012.

How to cite: Lefèvre, M., Tan, X., Lee, E., and Pierrehumbert, R.: Cloud-convection feedback in brown dwarfs atmosphere, European Planetary Science Congress 2021, online, 13–24 Sep 2021, EPSC2021-675, https://doi.org/10.5194/epsc2021-675, 2021.