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氧化铝表面二次电子发射抑制及其在微放电抑制中的应用
Secondary electron emission suppression on alumina surface and its application in multipactor suppression

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孟祥琛 1,2,3   王丹 1 *   蔡亚辉 1   叶振 4   贺永宁 1   徐亚男 5  
文摘 空间大功率微波器件中的二次电子倍增现象会诱发微放电效应,使得器件性能劣化或失效.针对加载氧化铝的同轴低通滤波器进行建模,并通过微放电阈值仿真验证了降低放电敏感表面的二次电子产额(SEY)可有效提升器件微放电阈值.针对器件中易于发生微放电的氧化铝表面,应用激光刻蚀制备表面微结构,获得孔隙比例为67.24%、平均深宽比例为1.57的微孔结构,氧化铝SEY峰值(δ_m)由2.46降低至1.10.应用磁控溅射工艺研究氮化钛(TiN)薄膜低SEY特性,当N_2与Ar流量比为7.5∶15时, TiN薄膜δ_m低至1.19.在激光刻蚀微结构氧化铝表面镀覆TiN薄膜,实现表面SEY的剧烈降低, δ_m降至0.79.通过仿真电子束辐照氧化铝表面带电特性,分析了表面带电水平对SEY的影响规律,以及低SEY表面抑制微放电的物理机制.选取填充了纯度为99.5%氧化铝片的同轴滤波器进行验证,结果表明:微结构氧化铝表面镀覆TiN薄膜后,器件微放电阈值由125 W增加至650 W.研究对于介质填充微波器件微放电效应抑制机理分析具有重要科学意义,对于提高微波器件微放电阈值具有工程应用价值.
其他语种文摘 For the high-power microwave (HPM) components applied to the space environment, the seed electrons in the components may resonate with the radio-frequency electrical field and may further lead the secondary electron multiplication to occur, triggering off the phenomenon of multipactor. Multipactor deteriorates the performance of the components, and in severe circumstances, it is even possible to result in the failure of the components or the spacecraft. Alumina ceramic possesses good dielectricity, high hardness, good thermal isolation, low dielectric loss, etc., so it is widely used in HPM systems including dielectric windows, and many other microwave components. However, alumina ceramic possesses a relatively high level of secondary electron yield (SEY or δ), indicating that the devastating effect of multipactor discharge is likely to be triggered off inside the alumina-filled HPM components in the space environment. In this work, the model of alumina loaded coaxil low pass fillter is simulated to verify that reducing the SEY of the alumina surface is effective and necessary to improve the multipactor threshold. After that, we use several technologies to achieve an ultralow SEY on the alumina surface. Firstly, a series of microstructures with different porosities and aspect ratios is fabricated. The results indicate that the microstructure with 67.24% porosity and 1.57 aspect ratio shows an excellent low-SEY property, which is able to suppress the SEY peak value (δ_m) of alumina from 2.46 to 1.10. Then, various process parameters are used to fabricate TiN films on silicon sheets. Experimental results indicate that the TiN film achieves the lowest δ_m of 1.19 when the gas flow ratio of N_2∶Ar is 7.5∶15. Thereafter, we deposit TiN ceramic coating onto the laser-etched microstructure samples, and an ultralow δ_m of 0.79 is finally achieved on alumina surface. Then we implement a qualitative analysis to explore the influence of surface charge on the secondary electron emission and multipactor for the microstructured alumina surface, discuss the mechanism of low-SEY surfaces mitigating unilateral and bilateral multipactor. For verifying the actual effect of low-SEY technologies on the suppression of multipactor, we use the technologies of constructing microstructure and depositing TiN films on the alumina surface which is filled in the designed coaxial low pass filter. Finally, we obtain a significant improvement in the multipactor threshold for the filter, which increases from 125 W to 650 W, and the improvement is 7.16 dB. This work develops an effective method to reduce SEY for alumina, which is of great scientific significance in revealing the mechanism of multipactor for the dielectric-filled microwave components and also is of engineering application significance in improving the reliability of HPM components.
来源 物理学报 ,2023,72(10):107901 【核心库】
DOI 10.7498/aps.72.20222404
关键词 二次电子发射 ; 氧化铝 ; 微放电 ; 微结构
地址

1. 西安交通大学微电子学院, 西安, 710049  

2. 西安中科原子精密制造科技有限公司, 西安, 710119  

3. 中国科学院西安光学精密机械研究所, 西安, 710119  

4. 西安泰斯特检测技术有限公司, 西安, 710076  

5. 上海空间推进研究所, 上海空间发动机工程技术研究中心, 上海, 201112

语种 中文
文献类型 研究性论文
ISSN 1000-3290
学科 物理学
基金 国家自然科学基金 ;  陕西省重点研发计划 ;  上海市科委项目 ;  中国科学院重大科研仪器设备研制项目 ;  中国科学院重点部署项目
文献收藏号 CSCD:7485830

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1 舒盼盼 高功率微波介质窗气体侧击穿特性的粒子-蒙特卡罗碰撞模拟 物理学报,2024,73(23):235101
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