Department of Atmospheric and Oceanic Sciences, Laboratory for Climate and Ocean-Atmosphere Studies, Peking University, Beijing 100871, China.
Beijing Innovation Center for Engineering Science and Advanced Technology (BIC-ESAT), Peking University, Beijing 100871, China.
Environ Sci Technol. 2023 Sep 12;57(36):13439-13448. doi: 10.1021/acs.est.3c03039. Epub 2023 Aug 30.
Activation of cloud droplets of aerosol particles from biogenic precursors plays a critical role in Earth's climate system. However, the molecular-level understanding of the cloud condensation nuclei (CCN) activation process for secondary organic matter (SOM) is still lacking. Here, we reduced the gap by segregating SOM from α-pinene based on water solubility. The chemical composition and CCN activity of the solubility-segregated fractions of SOM were measured. The results demonstrated for the first time by laboratory experiment that highly oxygenated compounds such as hydroperoxides and highly oxygenated organic molecules are important contributors for the CCN activity of α-pinene SOM. Meanwhile, relatively less water-soluble species were also abundant. Analysis based on the Köhler theory demonstrated that less water-soluble compounds in SOM remain undissolved during the cloud activation process, suggesting that the traditional single-parameter parameterization for CCN activation would not be sufficient for representing the process. In combination with the recent developments in SOM formation chemistry, the present study helps in understanding the interactions between the biosphere and climate.
气溶胶粒子的生物成因前体云凝结核的激活在地球气候系统中起着关键作用。然而,对于次生有机物质(SOM)的云凝结核(CCN)激活过程的分子水平理解仍然缺乏。在这里,我们通过根据水溶性将 SOM 从α-蒎烯中分离来缩小差距。测量了 SOM 的溶解度分离部分的化学成分和 CCN 活性。实验结果首次表明,过氧化物和高度含氧有机分子等高度含氧化合物是α-蒎烯 SOM 的 CCN 活性的重要贡献者。同时,相对较少水溶性的物质也很丰富。基于 Köhler 理论的分析表明,SOM 中较少水溶性的化合物在云激活过程中仍未溶解,这表明传统的 CCN 激活单参数参数化不足以代表该过程。结合 SOM 形成化学的最新进展,本研究有助于理解生物界与气候之间的相互作用。
