多步等离子体蚀刻高纵横比硅纳米结构以制造金属膜

Xiaoli Zhu, Zihao Wang, Chenxu Zhu, Jiashi Shen, Babak Shokouhi, H. Ekinci, Bo Cui
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引用次数: 0

摘要

研究人员使用连续、多步骤 C4F8/SF6 等离子体对金属膜应用中的硅纳米结构进行了电感耦合等离子体蚀刻,以获得具有光滑侧壁的数十纳米级高纵横比 (HAR) 特征。在此过程中,随着蚀刻的进行,离子轰击和自由基传输在 HAR 纳米结构之间会发生显著变化,这给剖面控制带来了挑战。在气体比率固定的情况下,剖面角度会在大约 400 nm 的深度发生变化,从正锥度过渡到负锥度。此外,在使用三个不同气体比的独立蚀刻过程(即每一步后关闭等离子体)时,会产生波浪状的柱状轮廓。为了优化钝化和蚀刻,我们采用了三步 C4F8/SF6 等离子体蚀刻工艺,在不同的蚀刻深度采用不同的气体比。通过在每一步后保持等离子体开启,连续的三步工艺为调整具有平滑和垂直剖面的 HAR 纳米结构的蚀刻提供了更大的灵活性。使用适当的气体比率,制备出了直径为 71 纳米、高度为 1 微米的 Metalens 纳米结构。特征尺寸变化小于 10 纳米。这种拟议的连续多步骤工艺提高了在 C4F8/SF6 等离子体中蚀刻硅的可控性,促进了金属硅和其他纳米器件的纳米制造。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Multi-step plasma etching of high aspect ratio silicon nanostructures for metalens fabrication
Inductively coupled plasma etching of silicon nanostructures for metalens applications using a continuous, multi-step C4F8/SF6 plasma was investigated to achieve high aspect ratio (HAR) features down to tens of nanometers with smooth sidewalls. In the process, the ion bombardment and the free radical transport significantly change among HAR nanostructures as the etching progresses, posing challenges to profile control. With a fixed gas ratio, a change in the profile angle occurs at a depth of approximately 400 nm, transitioning from a positive taper to a negative one. Additionally, a wave-like pillar profile is produced when using three separate (i.e., plasma turned off after each step) etching processes with varying gas ratios. To optimize passivation and etching, we adopt a three-step C4F8/SF6 plasma etching process with varying gas ratios at different etching depths. By keeping the plasma on after each step, the continuous, three-step process provides more flexibility for tuning the etching of HAR nanostructures with smooth and vertical profiles. Metalens nanostructures with 71 nm diameter and 1 μm height were created using the appropriate gas ratio. The feature size variation is less than 10 nm. This proposed continuous, multi-step process improves the controllability of silicon etching in C4F8/SF6 plasma, facilitating the nanofabrication of silicon metalens and other nanodevices.
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