Minzi Zhai, Sijin Zhao, Hua Guo, Xiangcheng Li, Xuetao Shi, Mukun He, Yali Zhang* and Junwei Gu*. Bionic-structured electromagnetic interference shielding composites. Science Bulletin, 2025, 10.1016/j.scib.2025.04.074. 2023IF=18.8.(1區綜合類Top期刊�����,中國科技期刊卓越行動計劃-領軍類期刊項目)
https://doi.org/10.1016/j.scib.2025.04.074
Abstract
As electromagnetic pollution intensifies and the demand for high-precision electronic equipment increases, the development of high-performance, adaptable electromagnetic interference (EMI) shielding materials with high-performance and adaptability has become a research focus. Inspired by natural structures, bionic designs offer unique advantages for the fabrication of advanced EMI shielding materials. These materials provide effective electromagnetic wave attenuation and are lightweight, flexible, and environmentally adaptable, thereby overcoming the limitations of traditional EMI shielding materials. This review systematically summarises the latest advancements in bionic-structured EMI shielding composites. This paper first introduces the design principles of bionic structures and then focuses on typical bioinspired systems, including nacre, honeycomb, leaf vein structures, and other nature-inspired structures. This review further explores common fabrication techniques and the structure–property relationships of materials with such structures, with a particular focus on performance optimisation strategies. Additionally, we examine the conformational relationships and underlying mechanisms governing the performance enhancements of bionic-structured EMI shielding composites. The challenges and future prospects of bionic-structured EMI shielding composites are also analyzed. This review aims to provide theoretical insights into structural innovation and performance enhancement, promoting the application of bionic-structured EMI shielding composites in aerospace, smart wearables, and medical electronics. This paper is expected to pave the way for the development of next-generation electromagnetic protection materials.
隨著電磁污染問題的日益突出和電子設備精密化需求的不斷提升�����,開發兼具高效屏蔽性能與多場景適應性的新型電磁屏蔽材料已成為研究熱點���。受自然界生物啟發的仿生結構設計理念在構建高性能電磁屏蔽材料方面展現出獨特優勢�,基于仿生結構的電磁屏蔽材料不僅能夠實現電磁波的高效損耗��,還能有效集成輕量化����、柔性及環境適應性等實用特性�,從而突破了傳統電磁屏蔽材料的應用瓶頸。該綜述系統梳理了仿生結構電磁屏蔽材料的研究進展,從仿生結構設計原理出發��,重點剖析仿珍珠層結構�、蜂窩結構、葉脈結構和其他仿生結構等典型仿生體系的構建策略,詳細論述各類仿生結構電磁屏蔽材料的常用制備方法,并深入探討了仿生結構電磁屏蔽材料構效關系與性能優化機制�,指出了仿生結構電磁屏蔽材料面臨的挑戰�,并展望了其未來的研究方向���。該綜述旨在為仿生結構電磁屏蔽材料的結構創新與性能提升提供理論指導�,推動其在航空航天、智能穿戴、醫療電子等領域的應用,為電磁防護材料領域開拓新的發展方向�����。
第一作者:翟珉梓
郵件地址:zhaimz@mail.nwpu.edu.cn