材料科学
电磁屏蔽
复合材料
电磁干扰
电磁干扰
电介质
极化(电化学)
光电子学
电子工程
化学
物理化学
工程类
作者
Ming Fang,Liya Huang,Zhenrong Cui,Peng Yi,Haihan Zou,Xufeng Li,Gao Deng,Chunyan Chen,Zhi Geng,Junzhe He,Xin Sun,Jianglan Shui,Ronghai Yu,Xiaofang Liu
标识
DOI:10.1002/adfm.202418870
摘要
Abstract Hydrogels/organohydrogels show promise for flexible, intelligent electromagnetic interference (EMI) shielding, yet simultaneously achieving absorption‐dominated shielding performance, excellent mechanical properties and multi‐mode intelligent responsiveness remains challenging. This study presents a microcapacitor network strategy as an alternative to the traditional conductive percolation network for EMI shielding materials. Paraffin‐nanoclay/MXene core‐shell microspheres are uniformly integrated into the hydrogel matrix via in situ polymerization, forming a microcapacitor network where the microsphere shells and hydrogel serve as capacitor plates and dielectric layers, respectively. Microcurrents and interfacial polarization at capacitor plates, along with dipole polarization within dielectric layer, significantly promote EM wave attenuation for absorption‐dominated EMI shielding (absorption coefficient >0.7). Meanwhile, the abundant hydrogen bonds and paraffin phase synergistically enhance mechanical strength (≈0.64 MPa) and stretchability (elongation at break > 1000%). Due to the solid‐liquid phase transition of the paraffin phase in microspheres, organohydrogel exhibits a unique ability to retain high‐temperature shielding performance at room temperature. This feature enhances room‐temperature shielding effectiveness and enables multi‐mode intelligent responsiveness. Under the same room‐temperature deformation mode, it exhibits programmable shielding performance regulation in response to different external stimuli, following room‐temperature changes or simulating high‐temperature changes.
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