Si/C/N纳米粉体的吸波特性研究

无机材料学报

Si/C/N纳米粉体的吸波特性研究

焦桓; 罗发; 周万城

西北工业大学凝固技术国家重点实验室西安 710072

收稿日期:2001-04-09 修回日期:2001-06-14 出版日期:2002-05-20 网络出版日期:2002-05-20

Dielectric Properties of Si/C/N Nano Powders

JIAO Huan; LUO Fa; ZHOU Wan-Cheng

State Key Laboratory of Solidification Processing; Northwestern Polytechnical University; Xi an 710072; China

Received:2001-04-09 Revised:2001-06-14 Published:2002-05-20 Online:2002-05-20

摘要/Abstract

摘要： 采用ＸＲＤ研究了氮原子百分含量为１１．６１%的Ｓｉ/Ｃ/Ｎ纳米粉体的相组成,并测定了粉体介电常数根据介电常数,分别优化设计了单层和双层的吸波徐层,设计的吸波涂层对８~１８ＧＨｚ范围的电磁波有较好的吸收作用．设计厚度为２．７ｍｍ的单层吸波涂层,在８~１５ＧＨｚ范围内反射率＜－５ｄＢ设计厚度为２．８ｍｍ的双层吸波涂层,在８~１８ＧＨｚ频率范围内电磁波的反射率均＜－５ｄＢ,反射率＜－８ｄＢ的频带为６ＧＨｚ．针对纳米粉体的吸波特性,提出了Ｓｉ/Ｃ/Ｎ纳米粉体的吸波机理．

关键词: Si/C/N纳米粉体, 介电性能, 吸波结构优化设计, 吸波机理

Abstract: Si/C/N nano powders with 11.61% nitrogen were prepared by CVD. XRD pattern and permittivity of the powders were investigated. On the basis of permittivity of
the powders, radar absorber structures of single- and double-layer were designed. A single-layer absorber coating with a reflection coefficient less than --5dB in
the frequency range of 8--15GHz was designed with a thickness of 2.7mm. A double-layer radar absorber coating with a reflection coefficient less than --5dB
in the frequency range of 8--18GHz was also designed with a thickness of 2.8mm. The range of the reflection coefficient being less than --8dB was 6GHz for the designed
double-layer radar absorber. The radar absorbing mechanism of Si/C/N nano powders was also interpreted. The SiC microcrystalline in the nano composite powder dissolves
a great deal of nitrogen. The charged defects are caused by N atoms occupying the sites of C in SiC moved in response to the electric field. The dielectric relaxation caused
by the charged defects moved in response to the electric field is the main way of the Si/C/N nano powders with absorbing properties.

Key words: Si/C/N nano powder, permittivity, structure design, absorbing mechanism

中图分类号:

TB332

焦桓,罗发,周万城. Si/C/N纳米粉体的吸波特性研究[J]. 无机材料学报.

JIAO Huan,LUO Fa,ZHOU Wan-Cheng. Dielectric Properties of Si/C/N Nano Powders[J]. Journal of Inorganic Materials.

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