材料科学
发射率
双层
水分
纳米技术
图层(电子)
光热治疗
蒸发冷却器
电子设备和系统的热管理
多孔性
稳健性(进化)
主动冷却
热的
辐射冷却
工作(物理)
复合材料
机械工程
保温
下降(电信)
被动冷却
反射率
多孔介质
纳米颗粒
机制(生物学)
水冷
光电子学
散射
活动层
消散
工程物理
作者
Yu Wang,Dong Xie,Yasong Zhao,Fangmin Shen,Shuangjiang Feng,Zhiyong Liu,Wei She,Yunsheng Zhang,Dongliang Zhao,Cheng Liu
摘要
ABSTRACT Radiative‐evaporative synergistic passive cooling presents a promising sustainable strategy for building thermal management, yet integrating superior optical properties with effective moisture management and structural robustness remains challenging. Herein, a biomimetic hydrogel‐cement bilayer structure inspired by the plant root‐soil synergy mechanism is designed to overcome this limitation. This structure consists of a hydrogel upper layer and a porous cement lower layer. The upper layer handles spectral regulation and evaporative cooling, while the lower layer provides mechanical reinforcement and continuously replenishes water through soil‐like water storage. Irregular Al 2 O 3 nanoparticles create a multiscale porous structure in the hydrogel, which enhances light scattering and enables a remarkable solar reflectance of 97.87% together with a mid‐infrared emissivity of 99%. As a result, the bilayer system attains a sub‐ambient temperature drop of 9°C under intense sunlight. Following rainfall, the cooling enhancement reaches 14°C, and the stored water sustains evaporative cooling for over five days. This work demonstrates a multimodal synergy among optical regulation, moisture management, and interfacial reinforcement, offering a new design paradigm for adaptive radiative‐evaporative cooling materials in buildings.
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