Abstract
Abstract. Interactions of atmospheric aerosols with clouds influence cloud properties and modify the aerosol life cycle. Aerosol particles act as cloud condensation nuclei and ice nucleating particles or become incorporated into cloud droplets by scavenging. For an accurate description of aerosol scavenging and ice nucleation in contact mode, collision efficiency between droplets and aerosol particles needs to be known. This study derives the collision rate from experimental contact freezing data obtained with the ETH CoLlision Ice Nucleation CHamber (CLINCH). Freely falling 80 μm diameter water droplets are exposed to an aerosol consisting of 200 and 400 nm diameter silver iodide particles of concentrations from 500 to 5000 and 500 to 2000 cm−3, respectively, which act as ice nucleating particles in contact mode. The experimental data used to derive collision efficiency are in a temperature range of 238–245 K, where each collision of silver iodide particles with droplets can be assumed to result in the freezing of the droplet. An upper and lower limit of collision efficiency is also estimated for 800 nm diameter kaolinite particles. The chamber is kept at ice saturation at a temperature range of 236 to 261 K, leading to the slow evaporation of water droplets giving rise to thermophoresis and diffusiophoresis. Droplets and particles bear charges inducing electrophoresis. The experimentally derived collision efficiency values of 0.13, 0.07 and 0.047–0.11 for 200, 400 and 800 nm particles are around 1 order of magnitude higher than theoretical formulations which include Brownian diffusion, impaction, interception, thermophoretic, diffusiophoretic and electric forces. This discrepancy is most probably due to uncertainties and inaccuracies in the description of thermophoretic and diffusiophoretic processes acting together. This is, to the authors' knowledge, the first data set of collision efficiencies acquired below 273 K. More such experiments with different droplet and particle diameters are needed to improve our understanding of collision processes acting together.
Highlights
Interactions of atmospheric aerosols with clouds influence the cloud properties and modify the aerosol life cycle
Error bars shown represent an uncertainty in the frozen fraction due to the classification uncertainty originating from the measurement errors of the Ice Optical Detector (IODE) detector (Lüönd et al, 2010)
This study uses contact freezing experiments of freely falling 80 μm diameter droplets exposed to an aerosol consisting of silver iodide particles
Summary
Interactions of atmospheric aerosols with clouds influence the cloud properties and modify the aerosol life cycle. 273 K solid aerosol particles that activate to cloud droplets may induce droplet freezing in immersion mode when the temperature is further decreased. This freezing process is usually discriminated from condensation freezing, where CCN activation is immediately followed by ice formation. When interstitial aerosol particles collide with supercooled cloud droplets they may induce freezing in contact mode This nucleation process deserves special attention, since it is reported to induce ice nucleation at a higher temperature than when the same particle acts as INP in immersion or condensation mode (Durant and Shaw, 2005; Fornea et al, 2009; Ladino Moreno et al, 2013). The importance of contact nucleation for cloud glaciation de-
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