润湿
材料科学
接触角
曲率
莲花效应
纳米技术
复合材料
化学
几何学
数学
有机化学
原材料
作者
Huimin Hou,Xiaomin Wu,Zhifeng Hu,Sihang Gao,Yuxi Wu,Yukai Lin,Liyu Dai,Guisheng Zou,Lei Liu,Zhiping Yuan
标识
DOI:10.1016/j.jcis.2023.06.113
摘要
Most droplets on high-efficiency condensing surfaces have radii of less than 100 μm, but conventional droplet transport methods (such as wettability-gradient surfaces and structural-curvature-gradient surfaces) that rely on the unbalanced force of three-phase lines can only transport millimeter-sized droplets efficiently. Regulating high-speed directional transport of condensate droplets is still challenging. Therefore, we present a method for condensate droplet transportation, based on the reaction force of the superhydrophobic saw-tooth surfaces to the liquid bridge, the condensate droplets could be transported at high speed and over long distances. The superhydrophobic saw-tooth surfaces are fabricated by femtosecond laser ablation and chemical etching. Condensation experiments and luminescent particle characterization experiments on different surfaces are conducted. Aided by the theoretical analysis, we illustrate the remarkable performance of condensate droplet transportation on saw-tooth surfaces. Compared with conventional methods, our method improves the transport velocity and relative transport distance by 1–2 orders of magnitude and achieves directional transport of the smallest condensate droplet of about 2 μm. Furthermore, the superhydrophobic saw-tooth surfaces enable multi-hop directional jumping of condensate droplets, leading to cross-scale increases in transport distances from microns to decimeters.
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