Enhanced dielectric loss in N-doped three-dimensional porous carbon for microwave absorption

IF 8.1 2区 材料科学 Q1 MATERIALS SCIENCE, MULTIDISCIPLINARY
Lei Ma, Yueyang Wu, Zhiwei Wu, Pengkun Xia, Yuxin He, Lin Zhang, Hui Fan, Chuanjia Tong, Long Zhang, Xiaohui Gao, Lianwen Deng
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Abstract

In this work, a three-dimensional porous carbon structure was constructed in situ by connecting carbon polyhedrons with graphitic nanosheets. The rich pores, high nitrogen doping content, and abundant defects formed on the surface provided multiple antennas to absorb electromagnetic waves. The optimized reflection loss of the material was as low as −41.65 dB with an effective absorption band of 5.84 GHz, which covered the entire Ku band. A mechanistic investigation based on density functional theory calculations and electrochemical analysis shows that the dipole loss and conduction loss were mainly caused by pyrrolic nitrogen and the higher electron mobility in the prepared materials. The conduction loss and polarization loss synergistically improve the absorption performance of nanosheet-linked porous carbon (NLPC). Furthermore, the potential practical application performance of the material, which was evaluated by computer simulation technology (CST), showed that all simulated RCS values were lower than 20 dBm2. Thus, this work provides new insights and methods to understand the microwave absorption properties of carbon materials.

Abstract Image

掺氮三维多孔碳的微波吸收介质损耗增强
在这项工作中,通过将碳多面体与石墨纳米片连接在一起,原位构建了三维多孔碳结构。丰富的孔隙、高氮掺杂含量以及表面形成的大量缺陷为电磁波的吸收提供了多重天线。优化后材料的反射损耗低至- 41.65 dB,有效吸收波段为5.84 GHz,覆盖了整个Ku波段。基于密度泛函理论计算和电化学分析的机理研究表明,偶极子损耗和导通损耗主要是由吡啶氮和材料中较高的电子迁移率引起的。传导损失和极化损失协同提高了纳米片连接多孔碳(NLPC)的吸收性能。此外,通过计算机模拟技术(CST)对材料的潜在实际应用性能进行了评估,结果表明,所有模拟RCS值都低于20 dBm2。因此,本工作为理解碳材料的微波吸收特性提供了新的见解和方法。
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来源期刊
Materials Today Advances
Materials Today Advances MATERIALS SCIENCE, MULTIDISCIPLINARY-
CiteScore
14.30
自引率
2.00%
发文量
116
审稿时长
32 days
期刊介绍: Materials Today Advances is a multi-disciplinary, open access journal that aims to connect different communities within materials science. It covers all aspects of materials science and related disciplines, including fundamental and applied research. The focus is on studies with broad impact that can cross traditional subject boundaries. The journal welcomes the submissions of articles at the forefront of materials science, advancing the field. It is part of the Materials Today family and offers authors rigorous peer review, rapid decisions, and high visibility.
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