复合数
材料科学
泄漏(经济)
对偶(语法数字)
复合材料
自由水
化学工程
环境科学
环境工程
工程类
文学类
宏观经济学
艺术
经济
作者
Yaohui Feng,Wenwen Wang,Quanwen Pan,R.Z. Wang,Tianshu Ge
标识
DOI:10.1021/acsmaterialslett.5c00340
摘要
Solar-driven sorption-based atmospheric water harvesting (SAWH) is a transformative solution to the water crisis. Despite the promise of hygroscopic salt-embedded composites, their practical application in SAWH is still impeded by the potential risk of leakage and released sorption heat. Here, inspired by the asymmetric architecture of plant leaves, a dual-functional composite is designed. The cost-effective and scalable nanofibers are embedded with hygroscopic salt and functionalized by polydimethylsiloxane to confer hydrophobic properties and high emissivity, ensuring the high salt content without leakage and mitigating the sorption heat by radiative cooling. The synergistic enhancements result in a water uptake of 6.12 g/g and a maximum temperature reduction of 6.2 °C. The demonstration of practical water harvesting achieves a 148% improvement in water sorption capacity and a sustained daily yield of 5.4 g/g over 3 days of continuous operation. This biomimetic design overcomes the traditional limitations of salt-based composites, offering a promising strategy for efficient water harvesting.
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