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垂直表面的亚环境日间辐射冷却

Subambient daytime radiative cooling of vertical surfaces.

作者信息

Xie Fei, Jin Weiliang, Nolen J Ryan, Pan Hao, Yi Naiqin, An Yang, Zhang Zhiyu, Kong Xiangtong, Zhu Fei, Jiang Ke, Tian Sicong, Liu Tianji, Sun Xiaojuan, Li Longnan, Li Dabing, Xiao Yun-Feng, Alu Andrea, Fan Shanhui, Li Wei

机构信息

GPL Photonics Laboratory, Key Laboratory of Luminescence Science and Technology, Chinese Academy of Sciences & State Key Laboratory of Luminescence and Applications, Changchun Institute of Optics, Fine Mechanics and Physics, Chinese Academy of Sciences, Changchun, 130033, China.

University of Chinese Academy of Sciences, Beijing 100039, China.

出版信息

Science. 2024 Nov 15;386(6723):788-794. doi: 10.1126/science.adn2524. Epub 2024 Nov 14.

DOI:10.1126/science.adn2524

PMID:39541474

Abstract

Subambient daytime radiative cooling enables temperatures to passively reach below ambient temperature, even under direct sunlight, by emitting thermal radiation toward outer space. This technology holds promise for numerous exciting applications. However, previous demonstrations of subambient daytime radiative cooling require surfaces that directly face the sky, and these cannot be applied to vertical surfaces that are ubiquitous in real-world scenarios such as buildings and vehicles. Here, we demonstrate subambient daytime radiative cooling of vertical surfaces under peak sunlight using a hierarchically designed, angularly asymmetric, spectrally selective thermal emitter. Under peak sunlight of about 920 watts per square meter, our emitter reaches a temperature that is about 2.5°C below ambient temperature, corresponding to a temperature reduction of about 4.3° and 8.9°C compared with a silica-polymer hybrid radiative cooler and commercial white paint, respectively.

摘要

亚环境日间辐射冷却能够通过向外太空发射热辐射，使温度被动地降至环境温度以下，即使是在直射阳光下也是如此。这项技术在众多令人兴奋的应用中具有广阔前景。然而，以往亚环境日间辐射冷却的演示需要直接面向天空的表面，而这些表面无法应用于建筑物和车辆等现实场景中普遍存在的垂直表面。在此，我们使用分层设计、角度不对称、光谱选择性的热发射体，展示了在阳光峰值照射下垂直表面的亚环境日间辐射冷却。在每平方米约920瓦的阳光峰值照射下，我们的发射体达到的温度比环境温度低约2.5°C，分别比二氧化硅 - 聚合物混合辐射冷却器和商用白色涂料的温度降低约4.3°C和8.9°C。

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垂直表面的亚环境日间辐射冷却

Subambient daytime radiative cooling of vertical surfaces.

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