The molecular scale mechanism of deposition ice nucleation on silver iodide†

IF 2.8 Q3 ENVIRONMENTAL SCIENCES Environmental science: atmospheres Pub Date : 2023-12-21 DOI:10.1039/D3EA00140G
Golnaz Roudsari, Mária Lbadaoui-Darvas, André Welti, Athanasios Nenes and Ari Laaksonen
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Abstract

Heterogeneous ice nucleation is a ubiquitous process in the natural and built environment. Deposition ice nucleation, i.e. heterogeneous ice nucleation that – according to the traditional view – occurs in a subsaturated water vapor environment and in the absence of supercooled water on the solid, ice-forming surface, is among the most important ice formation processes in high-altitude cirrus and mixed-phase clouds. Despite its importance, very little is known about the mechanism of deposition ice nucleation at the microscopic level. This study puts forward an adsorption-based mechanism for deposition ice nucleation through results from a combination of atomistic simulations, experiments and theoretical modelling. One of the most potent laboratory surrogates of ice nucleating particles, silver iodide, is used as a substrate for the simulations. We find that water initially adsorbs in clusters which merge and grow over time to form layers of supercooled water. Ice nucleation on silver iodide requires at minimum the adsorption of 4 molecular layers of water. Guided by the simulations we propose the following fundamental freezing steps: (1) Water molecules adsorb on the surface, forming nanodroplets. (2) The supercooled water nanodroplets merge into a continuous multilayer when they grow to about 3 molecular layers thick. (3) The layer continues to grow until the critical thickness for freezing is reached. (4) The critical ice cluster continues to grow.

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碘化银沉积冰成核的分子尺度机制†
异质冰核形成是自然和建筑环境中无处不在的过程。沉积冰核,即异质冰核--根据传统观点--发生在亚饱和水蒸气环境中,并且在固体成冰表面没有过冷却水的情况下,是高空卷云和混合相云中最重要的成冰过程之一。尽管其重要性不言而喻,但人们对沉积冰在微观层面的成核机制知之甚少。本研究通过原子模拟、实验和理论建模相结合的结果,提出了基于吸附的沉积冰成核机制。实验室中最有效的冰核粒子替代物之一碘化银被用作模拟的基质。我们发现,水最初吸附在簇中,随着时间的推移,簇中的水逐渐合并和增长,形成过冷水层。碘化银上的冰核至少需要吸附 4 个分子层的水。在模拟的指导下,我们提出了以下基本冻结步骤:(1) 水分子吸附在表面,形成纳米液滴。(2) 当过冷的纳米水滴增长到大约 3 个分子层厚时,它们合并成一个连续的多层。 (3) 水层继续增长,直到达到冻结的临界厚度。(4) 临界冰簇继续增长。
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