Evolution of surface morphology and properties of diamond films by hydrogen plasma etching

IF 3.8 4区工程技术 Q2 CHEMISTRY, MULTIDISCIPLINARY

Green Processing and Synthesis Pub Date : 2023-01-01 DOI:10.1515/gps-2022-8110

Genjie Chu, Sijia Li, Ji-yun Gao, Li Yang, M. Hou, Shenghui Guo

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Abstract

Abstract The micron-scale diamond film was prepared using hydrogen and methane as the mixed gas supplies via self-developed 3 kW/2,450 MHz microwave plasma chemical vapor deposition (MPCVD) equipment. On this basis, the evolution of the surface morphology, hydrophobicity, and electrical properties of samples under different hydrogen plasma etching times was investigated. The results indicate that the crystal edge and the top of the diamond grain were preferentially etched when etching time is less than 30 min. The surface roughness reduced from 0.217 to 0.205 μm, and the resistance value decreases from 3.17 to 0.35 MΩ. However, as the etch time increases to 120 min, the etching depth increases, and the surface roughness was increased. Simultaneously, the contact angles increased from 62.8° to 95.9°, which indicates that the surface of the diamond films exhibits more pronounced hydrophobicity. The treatment time of hydrogen plasma has no significant effect on the resistance value in the range of 0.26–0.50 MΩ. The mechanism of surface etching by hydrogen plasma was also discussed.

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氢等离子体刻蚀金刚石膜表面形貌和性能的演变

摘要采用自行研制的3kw / 2450 MHz微波等离子体化学气相沉积(MPCVD)装置，以氢气和甲烷为混合供气制备了微米级金刚石膜。在此基础上，研究了不同氢等离子体刻蚀次数下样品表面形貌、疏水性和电学性能的变化。结果表明:当刻蚀时间小于30 min时，晶界和金刚石颗粒顶部优先被刻蚀;表面粗糙度从0.217 μm降低到0.205 μm，电阻值从3.17降低到0.35 MΩ。然而，随着蚀刻时间增加到120 min，蚀刻深度增加，表面粗糙度增加。同时，接触角从62.8°增加到95.9°，表明金刚石膜表面的疏水性更加明显。氢等离子体处理时间对电阻值在0.26 ~ 0.50 MΩ范围内无显著影响。讨论了氢等离子体表面刻蚀的机理。

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来源期刊

Green Processing and Synthesis CHEMISTRY, MULTIDISCIPLINARY-ENGINEERING, CHEMICAL

CiteScore

6.70

自引率

9.30%

发文量

审稿时长

7 weeks

期刊介绍： Green Processing and Synthesis is a bimonthly, peer-reviewed journal that provides up-to-date research both on fundamental as well as applied aspects of innovative green process development and chemical synthesis, giving an appropriate share to industrial views. The contributions are cutting edge, high-impact, authoritative, and provide both pros and cons of potential technologies. Green Processing and Synthesis provides a platform for scientists and engineers, especially chemists and chemical engineers, but is also open for interdisciplinary research from other areas such as physics, materials science, or catalysis.