材料科学
分子工程
微波食品加热
超材料
制作
光电子学
纳米技术
吸收(声学)
透射率
宽带
热的
纳米光子学
等离子体子
多物理
光致变色
极化(电化学)
应变工程
离子键合
碳纳米管
电磁辐射
各向异性
光子超材料
陶瓷
解耦(概率)
纳米尺度
复合材料
带宽(计算)
薄膜
光子学
作者
Peikun Wu,Shujuan Tan,Xin Yan,Ya Ning,Ruping Yang,Laifa Shen,Jing Zheng,Guangbin Ji
标识
DOI:10.1002/adfm.202532154
摘要
ABSTRACT The development of materials that simultaneously offer broadband electromagnetic protection, optical transparency, mechanical flexibility, and intelligent responsiveness remains a formidable challenge in the advancement of next‐generation smart windows. In this study, a synergistic design strategy that integrates multi‐component molecular engineering with in‐situ microphase separation was introduced, leading to the successful fabrication of a novel multifunctional ionogel. This approach enables the spatial decoupling of the mechanical framework from ion transport and polarization domains within a nanoscale bicontinuous structure, effectively addressing the trade‐off between mechanical strength and ionic conductivity. The optimized ionogel demonstrates an ultra‐wide effective absorption bandwidth of 8.08 GHz at a remarkably thin thickness of 1.72 mm, along with high visible‐light transmittance exceeding 93% and excellent mechanical properties, including a fracture strain of 406%. Furthermore, by incorporating photochromic molecules, the material exhibits light‐gated microwave absorption characteristics with reversible bandwidth tuning and achieves passive radiative cooling exceeding 22.83°C under simulated sunlight. Differential charge density calculations further confirm electron accumulation at the hard/soft phase interfaces, providing atomic‐scale evidence for interfacial polarization. This work establishes a new paradigm of microstructure‐driven molecular design, opening a new avenue for the development of next‐generation electromagnetic protection and thermal management systems.
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