# Aerosol dynamics on hot exoplanets: the role of radiation pressure

**Authors:** James E. Owen, Ruth A. Murray-Clay

arXiv: 2508.20175 · 2025-08-29

## TL;DR

This paper investigates how stellar radiation pressure influences aerosol particles in hot exoplanet atmospheres, affecting their dynamics, size, and observational spectral features, which is crucial for atmospheric characterization.

## Contribution

It introduces the role of radiation pressure in aerosol dynamics on highly-irradiated exoplanets, highlighting its impact on particle size, distribution, and spectral signatures.

## Key findings

- Radiation pressure can exceed planetary gravity for low-density exoplanets.
- It causes aerosols to grow more slowly, resulting in smaller particles.
- Radiation pressure affects transmission spectra, revealing less muted molecular features.

## Abstract

Aerosols appear to be ubiquitous in exoplanetary atmospheres. However because our understanding of the physical processes that govern aerosols is incomplete, their presence makes the measurement of atmospheric properties, such as molecular abundance ratios, difficult. We show that aerosol particles in highly-irradiated exoplanets experience an additional acceleration due to stellar radiation pressure. The strength of this radiative acceleration often exceeds the planet's gravity and can approach values of ~10-20x gravity's for low-density planets (typically sub-Saturns) hosting ~0.1--1 micron aerosols. Since these highly irradiated, low-density planets are often the best targets for atmospheric characterisation with current instrumentation, radiation pressure is likely an important process when considering aerosol dynamics. We find that radiation pressure accelerates hazes produced by photochemistry at high altitudes to faster terminal velocities, causing them to grow more slowly. Hence, the particles are smaller and have lower mass concentrations in the presence of radiation pressure. By simulating haze-like aerosols in a 2D equatorial band model, we show that radiation pressure steepens optical slopes in transmission spectra, resulting in less muted molecular features in the Near-IR and gives rise to a correlation between the strength of radiation pressure and the molecular feature amplitude. Furthermore, the interaction of zonal winds and radiation pressure impacts both the optical slopes and amplitudes on the individual morning and evening terminators.

## Full text

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## Figures

44 figures with captions in the complete paper: https://tomesphere.com/paper/2508.20175/full.md

## References

109 references — full list in the complete paper: https://tomesphere.com/paper/2508.20175/full.md

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Source: https://tomesphere.com/paper/2508.20175