成核
平流层
对流层
化学
硝酸
粒子(生态学)
辐射压力
星团(航天器)
云凝聚核
化学物理
冷凝
硫酸
气溶胶
粒子数
无机化学
三元运算
大气科学
光化学
沉积(地质)
大气化学
冰核
粒径
氢
硫酸盐
物理化学
丰度(生态学)
硝酸盐
卷云
冷凝粒子计数器
作者
Jing‐Feng Li,Ning An,Ling Liu,Feng‐Yang Bai,Qishen Huang,Pai Liu,Xiucong Deng,Yunhong Zhang,Xiuhui Zhang
标识
DOI:10.5194/acp-25-14237-2025
摘要
Abstract. In the upper troposphere and lower stratosphere (UTLS), new particles frequently form to seed cloud condensation nuclei (CCN), thereby affecting radiative forcing and global climate. Iodic acid (IA) particles have been widely detected in the UTLS; however, how they form is still largely unknown. Given the abundance of nitric acid (NA) and ammonia (NH3) in the UTLS and their nucleation potential, we explore the influence of NA and NH3 on IA nucleation by quantum chemical calculations and cluster dynamics simulations. The structural analysis indicates that NA and NH3 can cluster with IA via hydrogen bonds, halogen bonds, and electrostatic attractions between ions. The small-sized IA–NA–NH3 clusters have lower free energies than typical sulfuric acid (SA)–NA–NH3 clusters in the upper troposphere, exhibiting greater stability and higher nucleation efficiency. Moreover, the NA-enhanced effect on the established efficient IA–NH3 nucleation is more evident at lower temperatures, especially with richer NA and NH3. In the extremely low-temperature UTLS, the proposed IA–NA–NH3 ternary pathway dominates nucleation, while in the mid-troposphere with higher temperatures, the role of NA is minor due to its rapid evaporation. These findings underscore the important role of NA in iodine particle formation in the UTLS, offering mechanistic insights into the missing secondary particle sources.
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