高温电磁波吸收材料及其多功能一体化研究进展

doi:10.15541/jim20260064

摘要/Abstract

摘要： 电磁波吸收材料蓬勃发展刺激了其在不同领域的应用与功能集成。然而,在变温服役环境下,温度维度的引入使得现有电磁波吸收材料的材料类型与设计范式面临严重的挑战。开发面向极端高温与变温环境的新型高温吸波材料、形成宽温域电磁波吸收材料的设计范式、提出高温电磁波吸收材料的多功能集成方法,对于电磁波吸收材料在航空航天、隐身技术和先进电子技术等领域的应用具有重要意义。本文基于高温电磁波吸收材料近年来的研究成果,首先梳理和综述了高温电磁波吸收材料的分类,分析了各类材料面向变温环境时所存在的优缺点,讨论了材料的设计策略、性能优化机制以及存在的应用挑战。进而针对高温电磁波吸收材料所长期面临的服役温域狭窄的难题,总结与归纳了温度不敏感型高温吸波材料的设计方法。最后,基于电磁波吸收材料多功能一体化趋势,探讨了高温吸波材料实现多功能一体化的途径与应用前景。通过聚焦与厘清上述高温电磁波吸收材料所面临的关键问题及其研究方向,以期为高温电磁波吸收材料的进一步开发和应用提供参考。

关键词: 高温电磁波吸收材料, 温度相关介电常数, 变温电磁性能设计, 多功能一体化

Abstract: The rapid development of electromagnetic wave absorbing materials has greatly stimulated their applications and functional integration across diverse fields. However, under service environments involving variable temperatures, the introduction of the temperature dimension poses severe challenges to both the material systems and design paradigms of existing electromagnetic wave absorbers. In this context, the development of novel high-temperature absorbing materials for extreme high-temperature and temperature-varying environments, the establishment of design paradigms for electromagnetic wave absorbing materials operable over a broad temperature window, and the proposal of multifunctional integration strategies for high-temperature electromagnetic wave absorbing materials are of great significance for their applications in aerospace, stealth technology, and advanced electronic systems. Based on the recent progress in high-temperature electromagnetic wave absorbing materials, this paper first systematically reviews their classification and summarizes the major categories that have emerged in recent years. The respective advantages and limitations of these material systems in variable-temperature environments are then analyzed in detail. In addition, the paper discusses the corresponding design strategies, the mechanisms underlying performance optimization, and the practical challenges that still hinder their wider application. Furthermore, in response to the long-standing problem of the narrow service temperature window of high-temperature electromagnetic wave absorbing materials, this study summarizes and generalizes the design approaches for temperature-insensitive high-temperature absorbers. These approaches are expected to provide new insights into improving the stability of electromagnetic response across wide temperature ranges. Finally, in light of the growing trend toward multifunctional integration in electromagnetic wave absorbing materials, this paper further explores the feasible routes and potential application prospects for achieving multifunctional integration in high-temperature absorbing materials. By focusing on and clarifying the key issues currently faced by high-temperature electromagnetic wave absorbing materials, as well as the major directions for future research, this work aims to provide a useful reference for the further development, rational design, and practical application of high-temperature electromagnetic wave absorbing materials.

Key words: high-temperature electromagnetic wave absorbing materials, temperature-dependent permittivity, variable-temperature electromagnetic performance design, multi-functional integration

中图分类号:

TB34

王伟超, 汪刘应, 刘顾, 黄洁, 谷麒, 葛超群, 吴仁兵. 高温电磁波吸收材料及其多功能一体化研究进展[J]. 无机材料学报, DOI: 10.15541/jim20260064.

WANG Weichao, WANG Liuying, LIU Gu, HUANG Jie, GU Qi, GE Chaoqun, WU Renbing. High-Temperature Electromagnetic Wave Absorption Materials and Their Multi-functional Integration[J]. Journal of Inorganic Materials, DOI: 10.15541/jim20260064.

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