Preparation and optical properties of diamond thin films based on fused silica substrates

Qiao Liu, Kesheng Guo, Q. Hu, Shaoyi Hou, Yongneng Xiao, Lang Hu
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Abstract

Diamond and diamond film have excellent performance in optics, electricity, mechanics, chemical stability, etc. Compared with bulk materials, diamond film has low cost and short preparation period, and has good laser damage characteristics, which can replace traditional films to achieve high performance. The laserinduced damage threshold, optical properties and morphology of diamond films are closely related to the growth conditions. In this paper, high-quality diamond films suitable for laser applications were grown on the surface of fused silica by microwave plasma chemical vapor deposition, and the effects of gas flow ratio and temperature on the optical properties of diamond films were studied. The effect of particle morphology on electric field and temperature field. Studies have shown that the growth quality of nanocrystalline diamond films is closely related to the flow ratio of methane/hydrogen and the growth temperature. When the flow ratio of methane/hydrogen is 3%, and the growth temperature is around 800℃, the surface roughness of the film is the lowest. The diamond film shows a morphology of (111) facets, the grain size is in the 20~200nm range, and the transmittance can reach up to 70%. The simulation of the laser electric field and temperature rise with different surface grain shapes shows that the grains of (111) facet can cause the electric field to increase by 2~4 times, and the temperature rise reaches 40~60℃.
基于熔融石英衬底的金刚石薄膜的制备及其光学性能
金刚石及其薄膜在光学、电学、力学、化学稳定性等方面具有优异的性能。与块体材料相比,金刚石薄膜成本低、制备周期短,且具有良好的激光损伤特性,可替代传统薄膜实现高性能。金刚石薄膜的激光损伤阈值、光学性能和形貌与生长条件密切相关。采用微波等离子体化学气相沉积的方法在熔融二氧化硅表面生长出适合激光应用的高质量金刚石薄膜,研究了气体流量比和温度对金刚石薄膜光学性能的影响。颗粒形貌对电场和温度场的影响。研究表明,纳米晶金刚石薄膜的生长质量与甲烷/氢的流动比和生长温度密切相关。当甲烷/氢气的流量比为3%,生长温度在800℃左右时,膜的表面粗糙度最低。金刚石膜呈(111)面形貌,晶粒尺寸在20~200nm范围内,透光率可达70%。对不同表面晶粒形状的激光电场和温升的模拟表明,(111)面晶粒可使电场增大2~4倍,温升达到40~60℃。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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