# Prediction of sulphate hazes in the lower Venus atmosphere

**Authors:** Peter Woitke, Manuel Scherf, Christiane Helling, Paul B. Rimmer, Martin Ferus, Helmut Lammer, Fabian Weichbold, Kate\v{r}ina N\v{e}me\v{c}kov\'a, Petr Eminger, Jaroslav Ka\v{c}ina, Tereza Constantinou

arXiv: 2508.20790 · 2025-08-29

## TL;DR

This study models the composition, size distribution, and formation heights of aerosols in Venus's lower atmosphere, linking chemical processes to observed haze layers and particle charge effects.

## Contribution

It introduces an integrated chemical and physical model predicting aerosol composition, size, and charge distribution in Venus's lower atmosphere, aligning with recent observational data.

## Key findings

- Aerosol particles form at specific altitudes matching haze layers.
- Particles smaller than 0.3 microns can be lifted from the ground.
- Large particles (>1 micron) are confined near the surface.

## Abstract

We study the amount, size distribution and material composition of (sub-)mic aerosol particles in the lower Venus atmosphere < 50 km. Our GGchem phase-equilibrium model predicts metal-chloride and metal-fluoride molecules to be present in the gas over the Venus surface in trace concentrations < 2.E-12, in particular FeCl2, NaCl, KCl and SiF4. Using an improved version of the DiffuDrift model developed by Woitke et al.2020, we find that these molecules deposit to form solid potassium sulphate K2SO4, sodium sulphate Na2SO4, and pyrite FeS2 above about 15.5 km, 9.5 km and 2.4 km, respectively. These heights coincide well with the three potential haze layers found in the Pioneer Venus Large Probe neutral mass spectrometer data by Mogul et al.2023. The particles with radius < 0.3 mic can be dredged up from the ground to reach the sulphuric acid cloud base from below by diffusion. The particle density decreases from ~ 5000/cm3 at ground level to ~100/cm3 at a height of 45 km. Particles larger than about 1 mic are found to stay confined to the ground < 10 km, indicating that the larger, so-called mode 3 particles, if they exist, cannot originate from the surface. All particles are expected to be coated by a thin layer of FeS2, Na2SO4 and K2SO4. We have included the repelling effect of particle charges on the coagulation, without which the model would predict much too steep gradients close to the surface, which is inconsistent with measured opacity data. Our models suggest that the particles must have at least 100 negative charges per micron of particle radius at ground level, and > 50/mic at a height of 45 km.

## Full text

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## Figures

11 figures with captions in the complete paper: https://tomesphere.com/paper/2508.20790/full.md

## References

127 references — full list in the complete paper: https://tomesphere.com/paper/2508.20790/full.md

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Source: https://tomesphere.com/paper/2508.20790