材料科学
辐射冷却
润湿
涂层
发射率
图层(电子)
热舒适性
复合材料
蒸发
热的
被动冷却
蒸发冷却器
辐射传输
基质(水族馆)
聚氨酯
光学
石墨烯
纳米技术
光电子学
镜头(地质)
空气层
灵活性(工程)
机械工程
接触角
水冷
辐射冷却
低发射率
主动冷却
高效能源利用
热辐射
智能聚合物
热导率
杰纳斯
光子学
红外线的
散射
作者
Nannan Dong,Jiating Wen,Fanglong Zhu,Zhe Sun
标识
DOI:10.1021/acsapm.5c04474
摘要
Integrating zero-energy cooling technology into personal thermal management (PTM) systems offers an effective approach to prevent heat-related illnesses and reduce energy consumption. Although materials designed for passive radiative cooling have been introduced, achieving an optimal balance between cooling efficiency and user comfort continues to pose a significant challenge. Here, we present a biomimetic personal thermal management (BPTM) fabric that couples passive radiative cooling with transpiration-like evaporative cooling through a hierarchical trilayer polymer architecture. The top layer consists of an electrospun cellulose acetate (CA) nanofibrous photonic coating loaded with Al2O3 nanoparticles, providing strong solar back scattering and (mid-infrared MIR) emission via the intrinsic vibrational bands of CA. A middle porous layer composed of polyurethane (PU)/CA establishes a wettability and pore-size gradient for self-driven, outward liquid transport. The bottom layer is a waterborne polyurethane (WPU) fabric substrate that imparts flexibility and wearer comfort. Owing to this trilayer design, the BTPM fabric exhibited favorable spectral selectivity, with around 92% sunlight reflection and 96% thermal emissivity in the atmospheric window. It also demonstrated Janus wettability (R = 340), achieved through electrospinning and hierarchical design, while maintaining superior moisture permeability. Temperature reductions of approximately 10 °C were observed in the BPTM fabric compared to that of commercial cotton. The fabric’s moisture-wicking properties (water evaporation rate of 0.21 g h–1) facilitate rapid sweat evaporation, cooling the skin so as to minimize the possibility of excessive sweating when exercising. Moreover, the fabric’s cost-effectiveness and wearability offer a promising direction for sustainable energy solutions, smart textiles, and applications focused on thermal comfort.
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