作为高效电磁波吸收器的 Fe3C/Fe 植入分层多孔碳

IF 4.3 3区 材料科学 Q2 MATERIALS SCIENCE, COATINGS & FILMS Diamond and Related Materials Pub Date : 2024-09-03 DOI:10.1016/j.diamond.2024.111556
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引用次数: 0

摘要

通信技术的飞速发展导致了严重的微波污染,这给微波吸收复合材料带来了挑战。目前的研究表明,要实现优异的微波吸收性能,需要采用多组分操作和巧妙的结构设计。因此,本研究采用碳化和酸蚀的方法制备了掺杂大量 Fe3C/Fe 纳米颗粒(Fe@CPC)的连续多孔碳(CPC)材料。通过平衡上述策略的优势,可以同时解决阻抗匹配差、单一损耗容量、磁性金属/合金易氧化以及传统吸收材料吸收带宽有限等问题。在石蜡基体中填料含量仅为 10 wt%的情况下,该材料在 1.9 mm 时的最小反射损耗为 -23.2 dB,有效吸收范围为 5.3 GHz。本文采用简单的方法制备了具有连续多孔结构的样品,由于制备方法得当,加上多组分复合材料的协同作用,样品具有优异的性能。多孔结构有利于大量活性位点的存在,从而实现大量金属离子的负载。此外,纳米粒子还能在表面聚集和分散。本文提出了一个理论框架,用于理解微波辐射通过界面极化和微尺度磁相互作用产生的协同效应。然而,在实现对结构设计的精确控制和确保金属元件的兼容集成方面,仍有一些障碍需要克服。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

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Fe3C/Fe implanted hierarchical porous carbon as efficient electromagnetic wave absorber

The rapid development of communication technology has led to severe microwave pollution, which presents a challenge for microwave-absorbing composites. Current research suggests achieving superior microwave absorption requires the use of multi-component operation and ingenious structural design. Consequently, the present study has prepared continuous porous carbon (CPC) materials doped with large amounts of Fe3C/Fe nanoparticles (Fe@CPC) using carbonization and acid etching. By balancing the advantages of the above strategies, it is possible to address issues such as poor impedance match, single loss capacity, easy oxidation of magnetic metals/alloys, and the limited absorption bandwidth of conventional absorbing materials at the same time. The material exhibits a minimum reflection loss of −23.2 dB with an efficient absorption range of 5.3 GHz at 1.9 mm at a filler content of just 10 wt% in the paraffin matrix. In this paper, the samples with a continuous porous structure were prepared by a simple method, and the properties were excellent due to the appropriate preparation method and the synergistic effect of the multi-component composite. The porous structure facilitates the presence of a considerable number of active sites, which enables the loading of a substantial quantity of metal ions. Furthermore, nanoparticles are capable of aggregating and dispersing on the surface. This paper presents a theoretical framework for understanding the synergistic effect of microwave radiation through interfacial polarization and micro-scale magnetic interaction. Nevertheless, there are still obstacles to overcome in terms of achieving precise control over the structural design and ensuring the compatible integration of metal components.

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来源期刊
Diamond and Related Materials
Diamond and Related Materials 工程技术-材料科学:综合
CiteScore
6.00
自引率
14.60%
发文量
702
审稿时长
2.1 months
期刊介绍: DRM is a leading international journal that publishes new fundamental and applied research on all forms of diamond, the integration of diamond with other advanced materials and development of technologies exploiting diamond. The synthesis, characterization and processing of single crystal diamond, polycrystalline films, nanodiamond powders and heterostructures with other advanced materials are encouraged topics for technical and review articles. In addition to diamond, the journal publishes manuscripts on the synthesis, characterization and application of other related materials including diamond-like carbons, carbon nanotubes, graphene, and boron and carbon nitrides. Articles are sought on the chemical functionalization of diamond and related materials as well as their use in electrochemistry, energy storage and conversion, chemical and biological sensing, imaging, thermal management, photonic and quantum applications, electron emission and electronic devices. The International Conference on Diamond and Carbon Materials has evolved into the largest and most well attended forum in the field of diamond, providing a forum to showcase the latest results in the science and technology of diamond and other carbon materials such as carbon nanotubes, graphene, and diamond-like carbon. Run annually in association with Diamond and Related Materials the conference provides junior and established researchers the opportunity to exchange the latest results ranging from fundamental physical and chemical concepts to applied research focusing on the next generation carbon-based devices.
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