用于高纵横比介质蚀刻的双频腔室中产生的高频等离子体的等离子模拟

IF 1.5 4区物理与天体物理 Q3 PHYSICS, APPLIED

Japanese Journal of Applied Physics Pub Date : 2024-09-17 DOI:10.35848/1347-4065/ad6e91

Shigeyuki Takagi, Shih-Nan Hsiao, Chih-Yu Ma, Makoto Sekine and Fumihiko Matsunaga

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引用次数: 0

摘要

对于高宽比超过 100 的三维 NAND 存储孔，有人提出了使用含氟化氢（HF）等离子体的蚀刻工艺。我们开发了一个气相反应仿真模型，可以再现实验中的高频等离子体。我们使用频率为 100 MHz 的电源生成高频等离子体，并测量了电子密度和 F 密度。模拟模型是根据以前论文中报告的碰撞截面和反应常数建立的，模拟中的 F 密度是通过与实验中的 F 密度进行比较而校准的。通过等离子体模拟，确定 F 密度和电子密度分别为 7.52 × 1016 m-3 和 8.50 × 1016 m-3。考虑到实验中的误差，我们认为模拟模型能够很好地再现实验中的高频等离子体。

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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Plasma simulation of HF plasma generated in dual-frequency chamber for high aspect ratio dielectric etching

For the 3D NAND memory hole with a high aspect ratio above 100, the etching process with hydrogen-fluoride (HF) contained plasmas has been proposed. We have developed a simulation model for gas-phase reactions that reproduces the HF plasma in experiments. The HF plasma was generated using a power supply of 100 MHz frequency, and electron and F densities were measured. The simulation model was constructed on the basis of the collision cross sections and reaction constants reported in the previous papers, and the F density in the simulation was calibrated by comparing it with that in the experiments. As a result of the plasma simulation, the densities of F and the electrons were determined to be 7.52 × 1016 m–3 and 8.50 × 1016 m–3, respectively. Taking into consideration the errors in the experiment, we considered that the simulation model is able to reproduce the experimental HF plasma well.

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来源期刊

Japanese Journal of Applied Physics 物理-物理：应用

CiteScore

3.00

自引率

26.70%

发文量

818

审稿时长

3.5 months

期刊介绍： The Japanese Journal of Applied Physics (JJAP) is an international journal for the advancement and dissemination of knowledge in all fields of applied physics. JJAP is a sister journal of the Applied Physics Express (APEX) and is published by IOP Publishing Ltd on behalf of the Japan Society of Applied Physics (JSAP). JJAP publishes articles that significantly contribute to the advancements in the applications of physical principles as well as in the understanding of physics in view of particular applications in mind. Subjects covered by JJAP include the following fields: • Semiconductors, dielectrics, and organic materials • Photonics, quantum electronics, optics, and spectroscopy • Spintronics, superconductivity, and strongly correlated materials • Device physics including quantum information processing • Physics-based circuits and systems • Nanoscale science and technology • Crystal growth, surfaces, interfaces, thin films, and bulk materials • Plasmas, applied atomic and molecular physics, and applied nuclear physics • Device processing, fabrication and measurement technologies, and instrumentation • Cross-disciplinary areas such as bioelectronics/photonics, biosensing, environmental/energy technologies, and MEMS