On the limits of Köhler activation theory: how do collision and coalescence affect the activation of aerosols?

On the limits of Köhler activation theory: how do collision and coalescence affect the activation of aerosols?

Activation is necessary to form a cloud droplet from an aerosol, and it is widely accepted that it occurs as soon as a wetted aerosol grows beyond its critical radius. Traditional Köhler theory assumes that this growth is driven by the diffusion of water vapor. However, if the wetted aerosols are la...

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Bibliographic Details
Published in:Atmospheric chemistry and physics Vol. 17; no. 13; pp. 8343 - 8356
Main Author: Hoffmann, Fabian
Format: Journal Article
Language:English
Published: Katlenburg-Lindau Copernicus GmbH 10-07-2017
Copernicus Publications
Subjects:
Activation
Aerosol concentrations
Aerosols
Cloud droplet collision
Cloud droplets
Clouds
Coalescence
Coalescing
Collection
Collections
Computer simulation
Droplets
Dye dispersion
Entrainment
Large eddy simulation
Large eddy simulations
Oceanic eddies
Particulates
Physics
Simulation
Theories
Theory
Vortices
Water vapor
Water vapour
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Description
Summary:Activation is necessary to form a cloud droplet from an aerosol, and it is widely accepted that it occurs as soon as a wetted aerosol grows beyond its critical radius. Traditional Köhler theory assumes that this growth is driven by the diffusion of water vapor. However, if the wetted aerosols are large enough, the coalescence of two or more particles is an additional process for accumulating sufficient water for activation. This transition from diffusional to collectional growth marks the limit of traditional Köhler theory and it is studied using a Lagrangian cloud model in which aerosols and cloud droplets are represented by individually simulated particles within large-eddy simulations of shallow cumuli. It is shown that the activation of aerosols larger than 0. 1 µm in dry radius can be affected by collision and coalescence, and its contribution increases with a power-law relation toward larger radii and becomes the only process for the activation of aerosols larger than 0. 4–0. 8 µm depending on aerosol concentration. Due to the natural scarcity of the affected aerosols, the amount of aerosols that are activated by collection is small, with a maximum of 1 in 10 000 activations. The fraction increases as the aerosol concentration increases, but decreases again as the number of aerosols becomes too high and the particles too small to cause collections. Moreover, activation by collection is found to affect primarily aerosols that have been entrained above the cloud base.
ISSN:1680-7324
1680-7316
1680-7324
DOI:10.5194/acp-17-8343-2017