辐射冷却
材料科学
辐射传输
光电子学
平面的
发射率
聚合物纳米复合材料
复合材料
氧化铟锡
墨水池
日光
纳米复合材料
氧化物
外观
光伏系统
不透明度
可扩展性
造型(装饰)
色散(光学)
工作(物理)
纳米技术
电
热辐射
光学
光伏
热的
多孔性
氧化锡
聚合物
联轴节(管道)
镜头(地质)
被动冷却
粒子(生态学)
保温
块(置换群论)
低发射率
作者
Kai Zhou,Songtao Tang,Pranto Karua,Fukang Wu,Sungmin Hong,Diya Patel,Gwendolyn M. Reeser,Donald M. Cropek,Paul V. Braun,Lili Cai
标识
DOI:10.1038/s41467-025-67831-0
摘要
Space cooling and lighting together consume 25% of global electricity, yet existing daytime radiative coolers are mostly limited to porous planar coatings that block visible light and lack durability. Here, we introduce rheology-optics coupling as a design principle that links polymer viscoelasticity to particle dispersion and optical scattering. Guided by this principle, we develop printable polydimethylsiloxane-zirconium oxide composites that achieve solar reflectance ( ~ 97.3%) and mid-infrared emissivity ( ~ 96.9%) comparable to the best reported values, despite a low filler loading of only ~4.5 vol.%. These scalable coatings provide up to 7.4 oC sub-ambient cooling and cut electricity use by 37% versus commercial paint in pilot-scale testing, while withstanding mechanical, thermal, and environmental stresses. Beyond planar coatings, the rheology-tunable polydimethylsiloxane-zirconium oxide ink enables direct ink writing of daylight-regulating architectures that deliver sub-ambient radiative cooling while admitting diffuse daylight for illumination, reducing both cooling and lighting demand. This work provides a practical and versatile platform for radiative cooling. Daytime radiative cooling materials typically require high filler loading or porosity. Here, authors introduce rheology–optics coupling to control particle dispersion, enabling printable low-filler PDMS–ZrO₂ composites for scalable and durable radiative coolers with versatile architectures.
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