Affiliation:
1. Department of Civil and Environmental Engineering and Earth Sciences University of Notre Dame Notre Dame Indiana
Abstract
Cloud microphysics fulfills a fundamental role in the formation and evolution of marine fog, but it is not fully understood. Numerous studies have addressed this by means of direct observations and modeling efforts. However, collision–coalescence of aerosols and fog droplets is a process often neglected. In this study we perform an analysis of the role of particle collections on the formation, development, and microphysical structure of marine fog. It was found that collisions open a path for aerosol activation by means of collisional activation. In addition, collisions contribute to the diffusional activation of fog particles by adding water mass to the growing aerosols, making them reach the required critical radius faster. Furthermore, collisions have a homogenizing effect on hygroscopicity, facilitating the activation of accumulation‐mode aerosols by increasing their diffusional growth.
Reference46 articles.
1. Revisiting Low and List (1982): Evaluation of raindrop collision parameterizations using laboratory observations and modeling;Barros A.P.;Journal of the Atmospheric Sciences,2008
2. Cloud droplet growth by collection;Berry E.X.;Journal of the Atmospheric Sciences,1967
3. An analysis of cloud drop growth by collection: Part I. Double distributions;Berry E.X.;Journal of the Atmospheric Sciences,1974
4. Bott A.(1998)Program for the solution of the stochastic coalescence equation: One‐dimensional cloud microphysics.https://doi.org/10.5281/zenodo.5660185.
5. Demistify: a large‐eddy simulation (LES) and single‐column model (SCM) intercomparison of radiation fog;Boutle I.;Atmospheric Chemistry and Physics,2022