Passive cooling paint enabled by rational design of thermal-optical and mass transfer properties

Fei, Jipeng; Zhang, Xuan; Han, Di; Yue, Lei; Xie, Fei; Zhou, Kai; Koh, See Wee; Ge, Junyu; Zhou, Hao; Wang, Xingli; Wu, Xinghui; Tan, Jun-Yan; Gu, Yuheng; Long, Yongping; Koh, Zhi Hui; Wang, Su; Du, Panwei; Mi, Tangwei; Ng, Bing Feng; Cai, Lili; Feng, Chi; Gan, Qiaoqiang; Li, Hong

doi:10.1126/science.adt3372

articleScienceJun 5, 2025Closed access

Passive cooling paint enabled by rational design of thermal-optical and mass transfer properties

JFJipeng Fei XZXuan Zhang DHDi Han LYLei Yue FXFei Xie

Nanyang Technological University · Beijing Institute of Technology · +7 more institutions

PubMed

Indexed incrossrefpubmed

Abstract

Integrating radiative and evaporative cooling shows promise for enhancing passive cooling, but durable self-curing integrated cooling paints remain underdeveloped. We designed a modified cementitious structure with advanced thermal-optical and mass transfer properties, boosting cooling power while ensuring durability, mechanical strength, and broad adhesion. The paint achieves 88 to 92% solar reflectance (depending on wetting), 95% atmospheric window emittance, ~30% water retention, and self-replenishing properties, maintaining stable optical performance even when wet. Field tests in tropical Singapore demonstrated superior cooling performance compared with commercial white paints. Pilot-scale demonstrations…

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75

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FWCI: 56.50
Percentile: 100%
References: 61

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Authors

23

Topics & keywords

Topics

Keywords

Materials science
Radiative cooling
Passive cooling
Thermal mass
Environmental science
Durability
Radiant cooling
Thermal emittance

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