材料科学
超材料
气凝胶
复合数
复合材料
低发射率
超材料吸收剂
热发射率
吸收(声学)
发射率
透射率
阻抗匹配
电介质
太赫兹辐射
反射损耗
保温
辐射传输
红外线的
辐射能
光子学
能量收集
热导率
渗流阈值
微波食品加热
光学
极化(电化学)
电磁学
太阳能
纳米复合材料
宽带
电磁辐射
热能
光子超材料
纳米技术
光电子学
作者
Jeong-Woo Lee,Jungkyu Choi,Junyong Seo,Jaemin Lee,Dowon Noh,Hoyoung Jang,Hwanju Lim,Jin‐Woo Park,Run Hu,Wonjoon Choi
标识
DOI:10.1002/adfm.202520521
摘要
Abstract Radiative cooling offers a compelling passive thermal management solution. However, conventional materials like aerogels and polymer films overlook essential domains such as mechanical integrity and electromagnetic interference control, which are critical for scalable applications. Inspired by reinforced concrete—where a lattice framework and bulk matrix synergistically deliver mechanical robustness and wave energy dissipation— a multiscale hierarchical metamaterial composite (MHMC) is developed that integrates a carbon black‐based metamaterial (CBM) with a cellulose acetate aerogel (CAA). Thermally, the gradient porous structure of CAA and high mid‐ and long‐wave infrared emissivity of the CBM enable efficient passive daytime radiative cooling, achieving a solar reflectance of 95.8% and emittance up to 93.1%. Outdoor testing confirms a maximum temperature reduction of −10.75 °C, outperforming pure CAA and Styrofoam. Electromagnetically, impedance matching of the CAA layer minimizes reflection across the C–Ku band (5.8–18 GHz), while interfacial polarization with CBM‐CAA enhances dielectric loss, yielding broadband absorption up to 95.2% and effective absorption bandwidths exceeding 11 GHz. Mechanically, aerogel reinforcement augments energy dissipation, reaching a peak energy absorption of 450.87 kJ m − 3 , substantially surpassing that of the individual constituents. The MHMC design strategy marks a promising milestone toward the paradigm shift from single‐functional materials to advanced multifunctional composites.
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