Imaging of pH distribution inside individual microdroplet by stimulated Raman microscopy.
Kedong GongJianpeng AoKejian LiLe LiuYangyang LiuGuanjun XuTao WangHanyun ChengZimeng WangXiuhui ZhangHaoran WeiChristian GeorgeAbdelwahid MelloukiHartmut HerrmannLin WangJianmin ChenMinbiao JiLiwu ZhangJoseph S FranciscoPublished in: Proceedings of the National Academy of Sciences of the United States of America (2023)
Aerosol microdroplets as microreactors for many important atmospheric reactions are ubiquitous in the atmosphere. pH largely regulates the chemical processes within them; however, how pH and chemical species spatially distribute within an atmospheric microdroplet is still under intense debate. The challenge is to measure pH distribution within a tiny volume without affecting the chemical species distribution. We demonstrate a method based on stimulated Raman scattering microscopy to visualize the three-dimensional pH distribution inside single microdroplets of varying sizes. We find that the surface of all microdroplets is more acidic, and a monotonic trend of pH decreasing is observed in the 2.9-μm aerosol microdroplet from center to edge, which is well supported by molecular dynamics simulation. However, bigger cloud microdroplet differs from small aerosol for pH distribution. This size-dependent pH distribution in microdroplets can be related to the surface-to-volume ratio. This work presents noncontact measurement and chemical imaging of pH distribution in microdroplets, filling the gap in our understanding of spatial pH in atmospheric aerosol.