自清洁和自冷却纤维素-纤维基分层复合材料

Yanpei Tian, Hong Shao, Xiaojie Liu, Fangqi Chen, Yongsheng Li, Changyu Tang, Y. Zheng
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摘要

被动日间辐射冷却(PDRC)通过同时反射阳光并通过地球大气窗口向寒冷的外层空间热辐射热量来冷却物体。然而,在实际应用中,目前的PDRC材料面临着前所未有的挑战,如复杂和昂贵的制造方法以及表面污染引起的性能下降。在这里,我们通过空气喷涂乙醇聚四氟乙烯(PTFE)微颗粒悬浮液嵌入纤维素纤维的微孔中,开发了具有优异自清洁和自冷却能力的可扩展纤维素纤维基分层复合材料。形成的超疏水PTFE涂层不仅可以保护纤维素纤维基纸免受水润湿和灰尘污染,还可以通过阳光后向散射增强其太阳反射率。在太阳直接辐照度为834 W/m2和671 W/m2时,其亚环境制冷性能为5℃,辐射制冷功率为104 W/m2。分层复合材料的自清洁表面延长了其使用寿命,并在室外应用中保持了良好的冷却性能。此外,染色的纤维素纤维纸可以吸收适当的可见光波长以显示特定的颜色,并有效反射近红外光以减少太阳加热,从而同步实现有效的辐射冷却和审美多样性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Self-Cleaning and Self-Cooling Cellulose-Fiber-Based Hierarchical Composites
Passive daytime radiative cooling (PDRC) cools an object down by simultaneously reflecting sunlight and thermally radiating heat to the cold outer space through the Earth's atmospheric window. However, for practical applications, current PDRC materials are facing unprecedented challenges such as complicated and expensive fabrication approaches and performance degradation arising from surface contamination. Here, we develop scalable cellulose-fiber-based hierarchical composites with excellent self-cleaning and self-cooling capabilities, through air-spraying ethanolic polytetrafluoroethylene (PTFE) microparticles suspensions embedded within the micropores of the cellulose fiber. The formed superhydrophobic PTFE coating not only protects the cellulose-fiber-based paper from water wetting and dust contamination for real-life applications but also reinforces its solar reflectance by sunlight backscattering. It results in a sub-ambient cooling performance of 5°C and radiative cooling power of 104 W/m2 under direct solar irradiance of 834 W/m2 and 671 W/m2, respectively. The self-cleaning surface of the hierarchical composites extends its lifespan and keep its good cooling performance for outdoor applications. Additionally, dyed cellulose-fiber-based paper can absorb appropriate visible wavelengths to display specific colors and effectively reflect near-infrared lights to reduce solar heating, which synchronously achieves effective radiative cooling and aesthetic varieties.
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