电磁屏蔽用纤维素基复合材料结构设计的研究进展

doi:10.13475/j.fzxb.20250206802

摘要/Abstract

摘要：

为应对5G高频通信技术发展带来的电磁干扰问题,开发轻量化、高性能的电磁屏蔽材料成为迫切需求。综述了纤维素纳米纤维(CNFs)基复合材料在电磁屏蔽应用中的最新研究进展,重点探讨了单层、多层、梯度结构的薄膜及多孔材料的设计方法,以及不同结构设计对电磁屏蔽性能的影响,总结了各类结构设计策略的优势不足及适用的不同领域。分析认为,单层结构难以实现填料均匀分布与良好屏蔽性能间的平衡;多层结构通过功能层的合理组合显著改善力学性能和屏蔽性能;梯度结构通过阻抗渐变和多重反射机制有效降低反射系数,展现出优异的宽频电磁屏蔽性能。多孔材料凭借其高孔隙率特性,通过多次反射和吸收机制提升屏蔽效果,同时保持低密度优势。指出未来研究可聚焦于开发低反射、耐久性优异的屏蔽材料,通过精准调控结构设计提升多维度性能。

关键词: 纤维素基复合材料, 纤维素纳米纤维, 电磁屏蔽, 结构设计, 屏蔽机制, 屏蔽性能

Abstract:

Significance This study focuses on the development of cellulose-based composite materials for electromagnetic interference (EMI) shielding, addressing the growing demand for lightweight and high-performance shielding materials in the era of 5G and beyond. With the rapid advancement of electronic technologies, including 5G communication, wearable devices, and autonomous driving, electromagnetic pollution has become a significant concern, posing risks to both human health and the functionality of electronic devices. Conventional metal shielding materials are limited by their high density and susceptibility to corrosion, making the development of alternative, sustainable, and multifunctional materials of utmost importance. Cellulose nanofibers (CNFs) offer a promising solution by virtue of their low density, high strength, flexibility, and renewable nature. This review highlights the structural design strategies of CNF-based composites and their impact on EMI shielding performance, providing new insights for the development of next-generation shielding materials.

Progress This paper comprehensively reviews the latest research progress in the structural design of CNF-based composites for EMI shielding. Single-layer, bilayer, and gradient structures of films and porous materials are discussed, along with their impacts on EMI performance. Single-layer structures have been widely studied for their simplicity and ease of fabrication. However, they often face limitations in achieving optimal impedance matching and high absorption efficiency by virtue of their uniform material distribution. In order to overcome these limitations, bilayer designs have been developed, which strategically combine conductive and magnetic layers to improve impedance matching and absorption capabilities. These designs leverage the synergistic effects of different material layers to enhance overall shielding performance. Gradient structures, inspired by natural systems, introduce gradual impedance transitions and multiple reflection/absorption pathways. By varying the composition and arrangement of materials within the structure, these designs can achieve ultra-low reflection coefficients and excellent shielding efficiency across broad frequency ranges. Porous materials, particularly aerogels, have also been extensively explored for their high porosity and lightweight nature. These materials enhance EMI shielding by extending the propagation path of electromagnetic waves through multiple reflections and absorptions within the porous network. Research has shown that optimizing the pore structure and incorporating conductive fillers can significantly improve the shielding effectiveness of aerogels while maintaining their low density. These innovations demonstrate the potential of CNFs-based composites to meet the diverse requirements of modern electronics through structural optimization and material integration.

Conclusion and Prospect The development of CNF-based composite materials for EMI shielding has achieved notable advancements, with various structural designs significantly enhancing shielding performance. However, several challenges remain. Current systems often exhibit high reflection coefficients, leading to potential secondary electromagnetic pollution, which is a critical issue that needs to be addressed. Future research should focus on improving impedance matching and reducing reflection losses to minimize secondary pollution. Additionally, enhancing the mechanical properties and durability of these composites is essential for practical applications. This includes optimizing the structural design to improve the composite's resistance to deformation and degradation over time. The development of low-reflection materials through advanced structural designs, such as asymmetric gradient structures and multi-layered composites with tailored material compositions, will be a key direction for future research. Exploring intelligent responsive structures that can adapt to varying electromagnetic environments will also be crucial. These structures could potential offer dynamic control over shielding properties, making them suitable for a wider range of applications. Furthermore, enhancing the structural integrity and long-term performance of composites under stress, through optimized fabrication processes and the incorporation of reinforcing agents, will be vital for their widespread adoption. Overall, continued innovation in structural design and material composition will be pivotal in advancing cellulose-based electromagnetic shielding materials, paving the way for their integration into emerging technologies, particularly in lightweight and flexible electronic devices.

Key words: cellulose-based composite, cellulose nanofiber, electromagnetic shielding, structure design, shielding mechanism, shielding property

中图分类号:

TN721.4

唐春霞, 王一帆, 毛云山, 刘健, 付少海. 电磁屏蔽用纤维素基复合材料结构设计的研究进展[J]. 纺织学报, 2025, 46(09): 36-45.

TANG Chunxia, WANG Yifan, MAO Yunshan, LIU Jian, FU Shaohai. Progress in structural design of cellulose-based composites for electromagnetic interference shielding[J]. Journal of Textile Research, 2025, 46(09): 36-45.

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链接本文: http://www.fzxb.org.cn/CN/10.13475/j.fzxb.20250206802

http://www.fzxb.org.cn/CN/Y2025/V46/I09/36

图/表 1

表1

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功能材料	厚度/μm	电磁屏蔽效能/dB	反射系数 R	力学强度/ MPa	适用领域	参考文献
Co-HCC/MXene/CNFs	200	45.6	0.25	—	6G通信、电子设备电磁屏蔽	[45]
CNFs/rGO/Fe₃O₄/AgNWs	67	112.9	—	115.2	可穿戴电磁屏蔽设备	[46]
CoFe₂O₄/MXene/AgNWs/CNFs	100	84.3	0.42	128.2	极端环境电子设备、个人热管理	[47]
CNF/MXene/AgNWs	35	65.4	—	194.3	航空航天、可穿戴设备	[48]
CNF/MXene/Fe₃O₄/CNTs	18	66.0	0.97	—	户外便携式设备、航空航天	[49]
CNT/CNF/PEDOT∶PSS	150	61.5	—	—	通信工程、航空航天	[50]