Size-resolved measurements of the ratios of cloud condensation nuclei (CCN) to condensation nuclei for particles with different hygroscopic growth factors (g) and distributions of g at 85% relative humidity were performed for urban aerosols over Nagoya, Japan. The CCN efficiency spectra of less hygroscopic particles (g of 1.0 and 1.1) were very different from those of more hygroscopic particles (g of 1.25 and 1.4). While the differences between the CCN activation diameters predicted from g (d(act,g85)) and those measured (d(act,CCN)) were within 12% for more hygroscopic particles, the differences were larger (16%-41%) for less hygroscopic particles. Possible causes of this included surface tension reduction, the dependence of kappa on the concentration of the solution, the existence of sparingly soluble materials, and asphericity of particles. The number concentrations of CCN (N-CCN) and cloud droplets (N-cd) and the effective radius of cloud droplets (R-eff) were estimated from the distributions of g using a cloud parcel model. The influences of the differences between d(act,g85) and d(act,CCN) and the existence of CCN-inactive particles on the model assessment were small. With high updraft velocity, incorporating both less and more hygroscopic particles into the model led to substantial increases in N-CCN and N-cd and a decrease in R-eff as compared to the hypothetical cases that only more hygroscopic particles were present. The results indicated that less hygroscopic particles significantly contribute to cloud droplet formation and assessments of g distributions are useful in this regard.

• 出版日期2014-3-27