Lightweight, High-Q and High Temperature Stability Microwave Cavity Resonators Using Carbon-Fiber Reinforced Silicon-Carbide Ceramic Composite

IF 6.9 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC IEEE journal of microwaves Pub Date : 2023-09-01 DOI:10.1109/JMW.2023.3305180
Lu Qian;Yeshodhara Baskaran;Matthias Krödel;César Miquel España;Laurent Pambaguian;Talal Skaik;Yi Wang
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Abstract

This article for the first time presents a high-Q cavity resonator manufactured using carbon-fiber reinforced silicon carbide (SiC) ceramic composite material HB-Cesic. This composite has attractive properties of low coefficient of thermal expansion comparable to Invar, low density similar to aluminum, and high thermal conductivity. Its manufacturing process enabled by machining and joining renders useful design flexibility. A high-Q spherical resonator has been used as an example in this investigation. Two resonators, one monolithic version and the other one based on split-block structure have been experimented. The end-to-end processes from machining, assembly or joining, to high-conductivity coating for both structures, have been demonstrated. The RF performance of the resonators and their variation with temperature have been measured. A quality factor of over 10000 has been achieved for both resonators at 11.483 GHz. The measured high thermal stability of the resonator correlates very well with the prediction. This work establishes the feasibility of using HB-Cesic in microwave resonators and paves the way for further development and verification programme for more complex passive microwave devices such as filters and multiplexers for space applications.
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使用碳纤维增强碳化硅陶瓷复合材料的轻质、高q和高温稳定性微波腔谐振器
本文首次提出了一种采用碳纤维增强碳化硅(SiC)陶瓷复合材料HB-Cesic制备的高q腔谐振器。该复合材料具有热膨胀系数低,与因瓦尔相当,密度低,与铝相似,导热性高的吸引人的性能。它的制造过程通过加工和连接提供了有用的设计灵活性。本文以高q球形谐振器为例进行了研究。实验了两种谐振器,一种是单片谐振器,另一种是基于分块结构的谐振器。从机械加工、装配或连接到两种结构的高导电性涂层的端到端工艺已经得到了证明。测量了谐振器的射频性能及其随温度的变化。在11.483 GHz下,两个谐振器的质量因数均超过10000。所测得的谐振腔的高热稳定性与预测结果非常吻合。这项工作确定了在微波谐振器中使用HB-Cesic的可行性,并为进一步开发和验证更复杂的无源微波器件(如用于空间应用的滤波器和多路复用器)的方案铺平了道路。
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审稿时长
8 weeks
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Front Cover Table of Contents Introduction to the Fall 2024 Issue IEEE Microwave Theory and Technology Society Information Over-the-Air Phase Noise Spectral Density Measurement for FMCW Radar Sensors
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