材料科学
辐射冷却
涂层
热致变色
发射率
被动冷却
光电子学
微型加热器
反射面
光学涂层
复合材料
光学
玻璃
热的
电子设备和系统的热管理
辐射传输
工作(物理)
低发射率
反射(计算机编程)
宽带
主动冷却
纳米技术
基质(水族馆)
相变材料
聚二甲基硅氧烷
超疏水涂料
智能材料
抛光
透射率
可扩展性
反射器(摄影)
作者
Ziqi Li,Akbar Bashir,Chak‐Yin Tang,Gary Chi‐Pong Tsui,Yan Chen,Jie Cui,Xing Ouyang,Chen Liu,Dazhu Chen
出处
期刊:Energy & environmental materials
[Wiley]
日期:2026-01-30
被引量:2
摘要
The rising global demand for energy‐efficient cooling highlights radiative cooling materials as a promising alternative to energy‐intensive air conditioning. However, most existing systems suffer from fixed optical properties, limited adaptability, and poor durability. This work presents a multifunctional, color‐adaptive radiative cooling coating that incorporates thermochromic microcapsules, hexagonal boron nitride, and hollow glass microspheres into a polydimethylsiloxane matrix via a scalable blending process. The coating exhibits a reversible thermochromic transition at ~45 °C, enabling dynamic spectral regulation that enhances solar reflection at elevated temperatures while suppressing overcooling at lower ones. Combined with broadband optical performance (solar reflectance of 91.7% and mid‐infrared emissivity of 94.3%), the coating achieves an average sub‐ambient cooling of 4.44 °C under outdoor conditions and a 6.7 °C reduction compared to commercial coatings in indoor simulation experiments. Beyond cooling efficiency, the micro/nano hierarchical surface imparts robust superhydrophobicity (contact angle >150°), self‐cleaning capability, and long‐term stability in corrosive, humid, and UV‐rich environments. By synergistically integrating adaptive optical regulation, high‐radiative cooling power, and durable surface protection, this work establishes a scalable strategy for next‐generation smart coatings, paving practical pathways toward energy‐saving buildings and sustainable thermal management technologies.
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