材料科学
纳米技术
多孔性
光催化
多孔介质
环境科学
水下
工艺工程
缩放比例
工作(物理)
化学工程
生物污染
淡水
3D打印
测距
地表水
水流
雾
饮用水净化
计算机科学
微流控
水处理
曲面(拓扑)
仿生材料
3d打印
作者
Junda Wu,Chunxiang Li,Jiangdong Dai,Yan Yan
标识
DOI:10.1038/s41467-025-65169-1
摘要
The efficiency of fog collection technologies is inherently hindered by the long-standing dilemma of capture vs. transportation balance. Inspired by nature, we address this issue by preserving hydrophilic bumps on slippery liquid-infused porous surfaces (SLIPS) through an underwater infusion strategy, creating a super-slippery fog collector with multi-scale biomimetic structures. This surface combines features from beetle carapaces and pitcher plant surfaces, enabling rapid initial water capture on hydrophilic bumps and efficient droplet transport. As a result, we develop the most efficient fog-collecting surface reported to date, harvesting 5000-60000 mg/cm² per hour with fog flow rates ranging from 300-1500 mL/h. By macroscopically scaling and optimizing, we construct an integrated 3D fog collecting device capable of harvesting over 660 g of water in 500 minutes. Further integrating TiO2 into the bumps imparts the ability for simultaneous water collection and purification without sacrificing collection efficiency. Our work reveals that resolving the capture-transport dichotomy is key to achieving high-efficiency fog water collection.
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