Study on Nitrogen Doped Hollow Cubic Carbon Electromagnetic Wave Absorbing Materials

IF 1.4 4区化学 Q4 PHYSICS, ATOMIC, MOLECULAR & CHEMICAL

Russian Journal of Physical Chemistry B Pub Date : 2025-09-09 DOI:10.1134/S199079312570054X

F. H. Huang, F. Yan, Z. J. Jing, J. W. Wen, S. Y. Li, Y. Chen

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Abstract

Carbon based materials have the characteristics of light weight, adjustable dielectric and stable performance, so they have become the most concerned wave absorbing materials. In this paper, phenolic resin was prepared with sodium chloride as template, and then L-lysine as nitrogen source was used to add nitrogen into phenolic resin, and the final nitrogen doped hollow cubic carbon material was obtained by etching after carbonization. During the experiment, the material with excellent wave absorbing performance was prepared by controlling the doping amount of nitrogen element. Finally, it was found that the nitrogen-doped hollow cubic carbon wave absorbing material could obtain the best reflection loss of –50.26 dB and the maximum effective bandwidth of 4.68 GHz at the extremely low load of 1.75 wt %. The one-component wave absorbing material can have good absorbing performance under very low load, which can become the best candidate material for lightweight and efficient electromagnetic wave absorber without adding other materials, and achieve the purpose of “wide, strong, light and thin.”

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氮掺杂空心立方碳电磁波吸波材料的研究

碳基材料具有重量轻、介电可调、性能稳定等特点，已成为人们最关注的吸波材料。本文以氯化钠为模板制备酚醛树脂，然后以l -赖氨酸为氮源向酚醛树脂中添加氮，碳化后通过蚀刻得到最终的氮掺杂空心立方碳材料。在实验过程中，通过控制氮元素的掺杂量，制备了具有优异吸波性能的材料。最后发现，在极低负载为1.75 wt %时，掺氮空心立方碳吸波材料的最佳反射损耗为-50.26 dB，最大有效带宽为4.68 GHz。单组分吸波材料在极低载荷下具有良好的吸波性能，无需添加其他材料即可成为轻量化高效电磁波吸收材料的最佳候选材料，达到“宽、强、轻、薄”的目的。

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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来源期刊

Russian Journal of Physical Chemistry B 化学-物理：原子、分子和化学物理

CiteScore

2.20

自引率

71.40%

发文量

106

审稿时长

4-8 weeks

期刊介绍： Russian Journal of Physical Chemistry B: Focus on Physics is a journal that publishes studies in the following areas: elementary physical and chemical processes; structure of chemical compounds, reactivity, effect of external field and environment on chemical transformations; molecular dynamics and molecular organization; dynamics and kinetics of photoand radiation-induced processes; mechanism of chemical reactions in gas and condensed phases and at interfaces; chain and thermal processes of ignition, combustion and detonation in gases, two-phase and condensed systems; shock waves; new physical methods of examining chemical reactions; and biological processes in chemical physics.