散热器(发动机冷却)
辐射冷却
短波
发射率
辐射传输
材料科学
热的
高温计
长波
共发射极
光电子学
热辐射
辐射热
宽带
环境科学
热导率
电子设备和系统的热管理
被动冷却
短波辐射
联轴节(管道)
遥感
核工程
大气(单位)
光学
雾
功率(物理)
热发射
作者
Zhi-Wei Zeng,Yi-Heng Ma,H Chen,Zi‐Chen Peng,Xu-Xu Jia,Jin-Xin Li,Fu‐Rong Zeng,Bo-Wen Liu,Yu-Zhong Wang,Xiao Xue,Haibo Zhao
摘要
Radiative cooling offers an energy-efficient pathway for dissipating heat from devices such as data centers, power systems, and industrial equipment. Yet, its application is constrained by the prevalence of vertical surfaces and the limited effectiveness of existing materials for objects operating above ambient temperature. Here, we report a thermal radiator featuring broadband mid-infrared emission and elevated shortwave emissivity (2.5-8 µm, 91.4%), designed to enhance radiative coupling with both the atmosphere and surrounding structures. This radiator significantly outperforms conventional selective emitters regarded as optimal for vertical ambient cooling. Under direct sunlight and a 600 W m-2 heat load on a vertical surface, the radiative cooler reduces device temperatures by approximately 18.6 °C and 27.0 °C compared to a selective emitter and an uncoated surface, respectively. The material further exhibits exceptional mechanical robustness, thermal stability, and environmental durability, highlighting its potential for real-world thermal management in vertically oriented, high-temperature systems.
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