材料科学
复合材料
复合数
多孔性
衰减
碳纳米管
纳米复合材料
空隙(复合材料)
电介质
导电体
介电损耗
反射损耗
吸收(声学)
聚酰胺
先进复合材料
聚合物
超临界流体
单元格大小
多孔介质
开裂
吸收能力
电磁辐射
不透明度
纳米纤维
作者
Menglong Xu,Biao Zhao,Ruiyang Tan,Dongdong Hu,Yajie Liu,Jun Wang,Linfeng Wei,Tao Liu,Ling Zhang,Ling Zhao,Chul B. Park
出处
期刊:Small
[Wiley]
日期:2025-09-30
卷期号:21 (44): e05493-e05493
被引量:2
标识
DOI:10.1002/smll.202505493
摘要
Abstract Porous conductive polymer composites (CPCs) have been proven to be potential electromagnetic wave (EMW) absorbers. However, challenges persist regarding the inferior absorption capacity and limited EMW attenuation mechanisms. Here, an eco‐friendly, scalable, and versatile route to fabricate lightweight and flexible microcellular foamed polyamide 6 (PA6)/carbon nanotube (CNT) nanocomposites with customized cellular structure and ultra‐high EMW absorption capacity via supercritical CO 2 foaming is proposed. The unique porous structure is verified to endow composite absorbents with good impedance matching and strong loss capacity simultaneously owning to their tunable dielectric properties and abundant interfaces. Moreover, the effects of CNT content and tailored microcellular architecture (i.e. varied void fraction under similar cell size, and varied cell size under similar void fraction) on the EMW absorbing performance are systematically investigated. Benefiting from the structural merits, the composite foam with void fraction of 44.1% and cell size of 21.7 µm delivers the ultra‐low reflection loss ( RL ) of −71.8 dB at a small thickness of 4.0 mm, demonstrating superior EMW absorption performance compared with vast majority of foamed CPCs. Subsequently, the Computer Simulation Technology (CST) simulation is performed to visualize the structural advantages of absorbers with varied cell size from the micro and macro perspective, and reveal the EMW attenuation evolutionary mechanism. The composite foam also possesses excellent mechanical and hydrophobic properties. By manipulating the microcellular architecture, this work paves a novel path toward developing lightweight, waterproofing, and high‐performance CPCs‐based absorbers.
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