Data supporting “Haze–cloud correlations mediated by supersaturation fluctuations”

Authors

• Hamed F. Sadi, Michigan Technological UniversityFollow
• Fan Yang, Brookhaven National Laboratory
• Jesse Anderson, Michigan Technological UniversityFollow
• Suryadey P. Singh, Michigan Technological UniversityFollow
• Will Cantrell, Michigan Technological UniversityFollow
• Raymond Shaw, Michigan Technological UniversityFollow

Document Type

Data

Publication Date

5-5-2026

Abstract

Atmospheric aerosol particles that contain water-soluble components can absorb water vapor in humid environments and form either haze particles or cloud droplets, depending on supersaturation conditions. Laboratory and in-situ measurements have shown that haze particles and cloud droplets often coexist and compete for available water vapor in shallow clouds and fogs, especially under polluted conditions. It is expected that more aerosol particles can form more haze particles and cloud droplets, so that the haze and cloud number concentrations are positively correlated. However, recent large-eddy simulations show that haze and cloud number concentration can be negatively correlated under extremely polluted conditions. Haze-cloud interactions across different environmental settings remain poorly understood. In this study, experiments in a convection cloud chamber with the same aerosol injection rate show that as supersaturation forcing increases (i.e., changing from polluted to clean conditions), the covariance between haze and cloud droplet number concentration changes from negative to positive, and finally to zero. Large-eddy simulations (LES) of the cloud chamber with a fixed supersaturation forcing but varying aerosol injection rates show a similar result for the haze--cloud correlation: near zero in clean, mean-supersaturation-dominated activation conditions; positive in moderate, supersaturation-fluctuation-influenced activation conditions; and negative in polluted, supersaturation-fluctuation-dominated activation conditions. A theoretical covariance framework was developed to interpret this behavior based on the relative magnitude and signs of the correlations between supersaturation and the populations of haze- and cloud-droplets. Significantly, experiments, LES, and theory all yield the same three-regime behavior for the sign of the haze--cloud covariance. Our results show that the haze--cloud covariance remains robust and easily measurable, thereby providing a useful metric for regime identification in the atmosphere, improving regime-aware parameterizations, and informing aerosol interventions such as fog dispersion, rainfall enhancement, and albedo modification.

Comments

This research was supported by NSF grant AGS-2133229. Fan Yang was funded by DOE as part of the Atmospheric System Research (ASR) program under contract DE-SC0012704. Suryadev Pratap Singh was supported by a grant from the Simons Foundation.

Recommended Citation

Fahandezh Sadi, H., Yang, F., Anderson, J.C., Pratap Singh, S., Cantrell, W. & Shaw, R.A. (2026) Haze–cloud correlations mediated by supersaturation fluctuations. Quarterly Journal of the Royal Meteorological Society, e70203.