材料科学
石墨烯
纤维
电阻率和电导率
复合材料
玻璃纤维
电导率
纳米技术
电气工程
化学
工程类
物理化学
作者
Kewen Huang,Fushun Liang,Jianbo Sun,Qinchi Zhang,Zhihao Li,Shuting Cheng,Wenjuan Li,Hao Yuan,Ruojuan Liu,Yunsong Ge,Yi Cheng,Kun Wang,Jun Jiang,Yuyao Yang,Mingyang Ma,Fan Yang,Ce Tu,Qin Xie,Wan‐Jian Yin,Xiaogang Wang,Yue Qi,Zhongfan Liu
标识
DOI:10.1002/adma.202313752
摘要
Abstract Conventional conductive materials such as metals are crucial functional components of conductive systems in diverse electronic instruments. However, their severe intrinsic impedance mismatch with air dielectric causes strong reflection of incident electromagnetic waves, and the resulting low electromagnetic transmissivity typically interferes with surrounding electromagnetic signal communications in modern multifunction‐integrated instruments. Herein, graphene glass fiber fabric (GGFF) that merges intrinsic electrical and electromagnetic properties of graphene with dielectric attributes and highly porous macrostructure of glass fiber fabric (GFF) is innovatively developed. Using a novel decoupling chemical vapor deposition growth strategy, high‐quality and layer‐limited graphene is prepared on noncatalytic nonmetallic GFF in a controlled manner; this is pivotal to realizing GGFF with the desired compatibility among high conductivity, low electromagnetic reflectivity, and high electromagnetic transmissivity. At the same sheet resistance over a wide range of values (250–3000 Ω·sq −1 ), the GGFF exhibits significantly lower electromagnetic reflectivity (by 0.42–0.51) and higher transmissivity (by 0.27–0.62) than those of its metal‐based conductive counterpart (CuGFF). The material design strategy reported herein provides a constructive solution to eliminate the incompatibility between electrical conductivity and electromagnetic transmissivity faced by conventional conductive materials, spotlighting the applicability of GGFF in electric heating scenarios in radar, antenna, and stealth systems.
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