Abstract
In light of the percentage of Earth’s cloud coverage, heterogeneous ice nucleation in clouds is the most important global-scale pathway. More recent parameterizations of ice nucleation processes in the atmosphere are based on the concept of ice nucleation active surface site density (ns). It is usually assumed that ns is independent of time and aerosol size distribution, i.e. that the surface properties of aerosols of the same species do not vary with size. However, the independence of ns on aerosol size for every species has been questioned. This study presents the results of ice nucleation processes of ATD laboratory-generated aerosol (particle diameters of 0 - 3 μm). Ice nucleation in the condensation mode was performed in a Dynamic Filter Processing Cham- ber at temperatures of -18°C and -22°C, with a saturation ratio with respect to water of 1.02. Results show that ns increased by lowering the nucleation temperature, and was also dependent on the particle size. The ns of particles collected on the filters, after a 0.5 μm D50 cut-off cyclone, resulted statistically higher with respect to the values obtained from the particles collected on total filters. The results obtained suggest the need for further investigation of ns dependence of same composition aerosol particles with a view to support weather and climate predictions.
Highlights
AFCoarse was obtained by subtracting the ice nucleating particles (INPs) counted on the filter after the cyclone from the total INP, divided by the difference between the particle number sampled on the total filter and the cyclone (see Equation (1))
Where INPT and INPPM0.5 are the ice nucleating particle numbers obtained from the total filter and the filter after the cyclone, respectively, and NpT and NpPM0.5 the total and the PM0.5 particle number
The paper shows the results of activated fraction (AF) and ns obtained from Arizona Test Dust (ATD) particles generated by nebulizing a 10 g∙L−1 suspension with high-purity air in a home-made Collison atomizer
Summary
Ice particles in the atmosphere can be formed via homogeneous ice nucleation in liquid water or heterogeneous ice nucleation triggered by relatively rare aerosol. It is well accepted that homogeneous ice nucleation is a time and temperature dependent stochastic process [1] [2] [3]. There is, ongoing debate as to whether heterogeneous ice nucleation is only temperature dependent or both temperature and time dependent [4]. Several published papers and theoretical considerations have evidenced that time plays a much weaker role than temperature [4] [5]-[11]
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