Topographical selective deposition: A comparison between plasma-enhanced atomic layer deposition/sputtering and plasma-enhanced atomic layer deposition/quasi-atomic layer etching approaches

Moustapha Jaffal, Taguhi Yeghoyan, G. Lefévre, R. Gassilloud, N. Possémé, C. Vallée, M. Bonvalot
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Abstract

In this work, we focus on the development of topographically selective deposition (TSD) leading to local deposition on the vertical sidewalls of 3D structures. A proof of concept is provided for the TSD of Ta2O5. The TSD process relies on plasma-enhanced atomic layer deposition (PEALD) alternating with quasi-atomic layer etching (ALE). Quasi-ALE involves a fluorination treatment followed by a directional Ar+ sputtering step. We show that the fluorination treatment allows a significant decrease in the incident kinetic energy of the subsequent directional Ar+ sputtering step. Conversely, when no fluorination step is carried out, TSD requires high incident kinetic energies during the directional Ar+ sputtering step, which, in turn, leads to detrimental plasma-induced damage on horizontal surfaces, such as roughness, also promoting by-product redeposition. The benefits and shortcomings of these two TSD approaches—PEALD/quasi-ALE and PEALD/energetic Ar+ sputtering—are compared in light of potential bottom-up technological developments.
地形选择性沉积:等离子体增强原子层沉积/溅射与等离子体增强原子层沉积/准原子层蚀刻方法的比较
在这项工作中,我们专注于地形选择性沉积(TSD)的发展,导致3D结构垂直侧壁上的局部沉积。为Ta2O5的TSD提供了概念验证。TSD工艺依赖于等离子体增强原子层沉积(PEALD)和准原子层蚀刻(ALE)交替进行。准ale涉及氟化处理,然后是定向Ar+溅射步骤。我们发现氟化处理可以显著降低后续定向Ar+溅射步骤的入射动能。相反,当不进行氟化步骤时,TSD在定向Ar+溅射步骤中需要很高的入射动能,这反过来会导致有害的等离子体诱导水平表面损伤,如粗糙度,也会促进副产物的再沉积。根据潜在的自下而上的技术发展,比较了两种TSD方法——PEALD/准ale和PEALD/高能Ar+溅射的优点和缺点。
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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