# Cloud formation in metal-rich atmospheres of hot super-Earths like 55   Cnc e and CoRot7b

**Authors:** G.Mahapatra (1), Ch.Helling (1), Y. Miguel (2) ((1) - Centre for, Exoplanet Science, University of St Andrews, (2) - Laboratoire Lagrange,, Observatoire de la C\^ote d'Azur)

arXiv: 1706.07219 · 2017-09-20

## TL;DR

This study investigates cloud formation in metal-rich atmospheres of hot super-Earths like 55 Cnc e and CoRoT-7b, highlighting how chemical composition and temperature influence cloud properties and formation likelihood.

## Contribution

It introduces a kinetic, non-equilibrium cloud formation model tailored for metal-rich exoplanet atmospheres, expanding understanding of cloud properties under varying chemical conditions.

## Key findings

- Mineral clouds likely form on 55 Cnc e and HD149026b.
- High temperatures on some super-Earths inhibit cloud formation due to ionization.
- Cloud particle sizes and compositions vary with elemental abundances.

## Abstract

Clouds form in the atmospheres of planets where they can determine the observable spectra, the albedo and phase curves. Cloud properties are determined by the local thermodynamical and chemical conditions of an atmospheric gas. A retrieval of gas abundances requires a comprehension of the cloud formation mechanisms under varying chemical conditions. With the aim of studying cloud formation in metal rich atmospheres, we explore the possibility of clouds in evaporating exoplanets like CoRoT-7b and 55 Cnc e in comparison to a generic set of solar abundances and the metal-rich gas giant HD149026b. We assess the impact of metal-rich, non-solar element abundances on the gas-phase chemistry, and apply our kinetic, non-equilibrium cloud formation model to study cloud structures and their details. We provide an overview of global cloud properties in terms of material compositions, maximum particle formation rates, and average cloud particle sizes for various sets of rocky element abundances. Our results suggest that the conditions on 55 Cnc e and HD149026b should allow the formation of mineral clouds in their atmosphere. The high temperatures on some hot-rocky super-Earths (e.g. the day-side of Corot-7b) result in an ionised atmospheric gas and they prevent gas condensation, making cloud formation unlikely on its day-side.

## Full text

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## Figures

20 figures with captions in the complete paper: https://tomesphere.com/paper/1706.07219/full.md

## References

60 references — full list in the complete paper: https://tomesphere.com/paper/1706.07219/full.md

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Source: https://tomesphere.com/paper/1706.07219