- Wu, Hao;
- Li, Zhanqing;
- Li, Hanqing;
- Luo, Kun;
- Wang, Yuying;
- Yan, Peng;
- Hu, Fei;
- Zhang, Fang;
- Sun, Yele;
- Shang, Dongjie;
- Liang, Chunsheng;
- Zhang, Dongmei;
- Wei, Jing;
- Wu, Tong;
- Jin, Xiaoai;
- Fan, Xinxin;
- Cribb, Maureen;
- Fischer, Marc L;
- Kulmala, Markku;
- Petäjä, Tuukka
A new mechanism of new particle formation (NPF) is investigated using comprehensive measurements of aerosol physicochemical quantities and meteorological variables made in three continents, including Beijing, China; the Southern Great Plains site in the USA; and SMEAR II Station in Hyytiälä, Finland. Despite the considerably different emissions of chemical species among the sites, a common relationship was found between the characteristics of NPF and the stability intensity. The stability parameter (ζ = Z/L, where Z is the height above ground and L is the Monin-Obukhov length) is found to play an important role; it drops significantly before NPF as the atmosphere becomes more unstable, which may serve as an indicator of nucleation bursts. As the atmosphere becomes unstable, the NPF duration is closely related to the tendency for turbulence development, which influences the evolution of the condensation sink. Presumably, the unstable atmosphere may dilute pre-existing particles, effectively reducing the condensation sink, especially at coarse mode to foster nucleation. This new mechanism is confirmed by model simulations using a molecular dynamic model that mimics the impact of turbulence development on nucleation by inducing and intensifying homogeneous nucleation events.