The formation of ice particles in the atmosphere strongly affects cloud properties and the climate. While scientists know mineral dust is an effective ice nucleating particle, the role of aerosols from human activities in ice nucleation remains under debate. In this study, researchers probed the ice nucleation ability of different aerosol types by combining 11-year observations from multiple satellites and cloud-resolving model simulations. The team found that, for strong convective cloud systems, the size of ice particles near cloud top decreased with increased amounts of polluted aerosols over land. The reduction in ice particle size was due to the freezing of cloud droplets, which are smaller under more polluted conditions, in the colder temperature regime (less than -38 C).

By contrast, moderate convection led to an increase in ice particle size with polluted continental aerosols. The model simulations suggest that this correlation was due to increased ice nucleation at relatively warmer temperatures (greater than -38 C) and prolonged ice particle growth in more polluted conditions. From these results, the team concluded that polluted continental aerosols from East Asia contained a considerable fraction of ice-nucleating particles, which enhanced ice formation at the relatively warmer temperatures. Similar aerosol–ice relationships were observed for dust aerosols, further corroborating the ice-nucleation ability of polluted continental aerosols. By spurring ice formation, aerosols from human activities could have profound impacts on cloud lifetime, cloud radiative effects such as absorbing or reflecting energy, and precipitation.