Selective isotropic atomic-layer etching of thin films by using dry chemical removal tool

Kazunori Shinoda, Nobuya Miyoshi, Hiroyuki Kobayashi, M. Izawa, K. Ishikawa, M. Hori
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Abstract

There has been considerable interest in the development of isotropic atomic layer etching (ALE) for the conformal removal of thin films. Material selectivity is crucial for the development of isotropic ALE because the next generation of semiconductor devices will be constructed with miniaturized 3D structures using a variety of very thin films. We developed plasma-assisted thermal-cyclic ALE, which is a repetition of surface modification by plasma exposure and removal of the modified surface by infrared heating. We developed a 300-mm tool, namely, dry chemical removal (DCR), which is equipped with an inductively coupled plasma (ICP) source and infrared lamps, to facilitate rapid thermal desorption of the modified surface. An important feature of the plasma-assisted thermal-cyclic ALE is that it has more tuning knobs than that of conventional ALE because it uses two temperatures: a low temperature for surface modification and an elevated temperature for the removal of the modified surface. This paper presents the selective ALE of various materials, i.e., Si3N4, TiN, W, and SiGe using the developed tool. The mechanisms of the selectivity are divided into two categories: formation of an ammonium salt-based modified layer and selectivity control by adjusting the infrared heating time. This paper reviews the selective ALE mechanisms, focusing on the results of in situ analysis of surface reactions, and presents some of the latest findings.
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用干法化学去除工具对薄膜进行选择性各向同性原子层蚀刻
各向同性原子层刻蚀(ALE)技术在薄膜保形去除中的应用引起了广泛的关注。材料选择性对于各向同性ALE的发展至关重要,因为下一代半导体器件将使用各种非常薄的薄膜构建小型化的3D结构。我们开发了等离子体辅助热循环ALE,这是通过等离子体暴露和红外加热去除修饰表面的重复表面修饰。我们开发了一种300毫米的工具,即干法化学去除(DCR),该工具配备了电感耦合等离子体(ICP)源和红外灯,以促进改性表面的快速热解吸。等离子体辅助热循环ALE的一个重要特点是,它比传统ALE有更多的调节旋钮,因为它使用两种温度:低温用于表面修饰,高温用于去除修饰表面。本文介绍了利用开发的工具对Si3N4、TiN、W和SiGe等多种材料的选择性ALE。选择性机理分为两类:铵盐基改性层的形成和通过调节红外加热时间控制选择性。本文综述了选择性ALE机制,重点介绍了表面反应的原位分析结果,并介绍了一些最新发现。
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