Significantly reduced secondary electron emission from silver/carbon composite films for microwave devices

Zhao, Yanan; Sun, Xuan; Hu, Taotao; Bai, He; He, Yun; Yang, Jing; Cui, Wanzhao; Hu, Zhongqiang; Liu, Ming

doi:10.1063/5.0088466

Journal of Applied Physics

2022

DOI: 10.1063/5.0088466

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Significantly reduced secondary electron emission from silver/carbon composite films for microwave devices

Yanan Zhao

Xuan Sun

Taotao Hu

et al.

Abstract: The micro-discharge effect is a failure mechanism that often appeared in space microwave devices under vacuum conditions, such as RF (radio frequency) cavity, RF satellite missile, and antenna launching communication system. How to control micro-discharge effectively and simply has become a research hotspot. In this paper, we have prepared a series of doping silver (Ag)/carbon (C) composite films by double target magnetron sputtering technology and have significantly reduced the maximum secondary electron emis… Show more

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2024

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Cited by 2 publications

References 28 publications

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Decreased Secondary Electron Emission from Aluminum Surface by a Fluorocarbon–Titanium Composite Film

Wang,

He,

Zhao

et al. 2024

ACS Omega

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Multipactor, a vacuum discharge under microwave conditions triggered by secondary electron emission (SEE), plays a critical role in managing the power level of microwave devices. In this study, we developed a fluorocarbon−titanium composite film on aluminum by cosputtering polytetrafluoroethylene (PTFE) and titanium via a controlled temperature and sputtering power ratio (RF power for PTFE to DC power for Ti) to suppress the SEE of Al. The evolution of microtopography and chemical composition of the composite film was evaluated. An increasing power ratio varying from 0.5 to 3.0 is found to change the film surface from scattered island-like bumps to a prominent peak−valley pattern and eventually to a smooth surface with few flat swellings. Elemental analysis revealed that the fluorine-to-carbon (F/C) mole ratio in samples was more significantly influenced by the sputtering power ratio than by the substrate temperature. The SEE yield indicates that the peak−valley pattern prepared by a power ratio of 2 leads to the maximum of the SEE yield curve reducing steeply from 2.99 to 1.23, which is attributed not only to the roughed pattern but also to the high F/C mole ratio owing to the higher capacity of electron trapping by the fluorine atoms.

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Decreased Secondary Electron Emission from Aluminum Surface by a Fluorocarbon–Titanium Composite Film

Wang,

He,

Zhao

et al. 2024

ACS Omega

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Effective improvement of the micro-discharge threshold and environmental stability in microwave devices based on carbon/silver/titanium composite films

Zhao,

Zhou,

Meng

et al. 2024

Journal of Applied Physics

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The micro-discharge effect limits the development of high-frequency microwave power components to miniaturization and integration. Therefore, it has become a focus of research to effectively suppress the micro-discharge effect, increase the micro-discharge threshold, and strengthen the environmental stability of high-frequency microwave devices. In this study, different elemental ratios of carbon (C)/silver (Ag)/titanium (Ti) composite films were obtained by multi-target magnetron co-sputtering technology and then systematically analyzed for micro-discharge effects. When the doping ratio of C/Ag/Ti was 3.538/1/0.013, the corresponding maximum secondary electron emission coefficient (δmax) decreased to 1.01 owing to the suppression of secondary electron emission by the increase in the content of sp2 hybrid bond. The micro-discharge threshold of Ku band waveguide filters coated with moderate C/Ag/Ti composite films showed an optimal performance of 10 000−12 500 W, which was increased by approximately 20 times. Moreover, the microstructure of the composite films exhibited higher density and flatness with a tiny increase in the titanium doping ratio, representing good environmental stability. Thus, the effective suppression of the secondary electron emission yield, significant improvement in the micro-discharge threshold, and enhancement of the environment stability of microwave components could be realized simultaneously by reasonably controlling the content of titanium in silver and titanium co-doped carbon-based composite films.

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Significantly reduced secondary electron emission from silver/carbon composite films for microwave devices

Cited by 2 publications

References 28 publications

Decreased Secondary Electron Emission from Aluminum Surface by a Fluorocarbon–Titanium Composite Film

Decreased Secondary Electron Emission from Aluminum Surface by a Fluorocarbon–Titanium Composite Film

Effective improvement of the micro-discharge threshold and environmental stability in microwave devices based on carbon/silver/titanium composite films

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