Thermal Scanning Probe Lithography (t-SPL) for Nano-Fabrication

2019 Pan Pacific Microelectronics Symposium (Pan Pacific) Pub Date : 2019-02-01 DOI:10.23919/PANPACIFIC.2019.8696898

H. Wolf, Y. Cho, S. Karg, P. Mensch, C. Schwemmer, A. Knoll, M. Spieser, Samuel Bisig, C. Rawlings, P. Paul, F. Holzner, U. Duerig

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引用次数: 1

Abstract

Thermal scanning probe lithography (t-SPL) is a direct-write patterning method that creates high-resolution features with a heated scanning probe tip in an organic resist material. It is able to produce dense high-resolution patterns with sub-20 nm half-pitch at ambient conditions which can be transferred into silicon substrates using a hard-mask patterning stack and reactive ion etching (RIE). Feature sizes of transferred lines can be as small as 7 nm. Linear write speeds of up to 20 mm/s can be achieved. Different from e-beam lithography (EBL), in t-SPL proximity effects are absent and substrate damage of sensitive materials caused by high energy electrons is avoided. A direct inspection of the patterned area is provided during the writing process. Overlay patterning without additional alignment marks onto pre-existing structures is another feature of the t-SPL method. Existing device structures can be located precisely under a resist stack with the local probe tip and the additional target structures can then be generated with $\lt 5$ nm-precise overlay alignment. One further strength of tSPL is the capability of producing 3D patterns. The process can be controlled to produce 3D structures with $\approx 1$ nm $(1 \sigma)$ depth accuracy. Examples of unique devices fabricated by tSPL will be discussed.

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热扫描探针光刻(t-SPL)纳米加工

热扫描探针光刻(t-SPL)是一种直接写入图案化方法，通过在有机抗蚀剂材料中加热扫描探针尖端来创建高分辨率特征。它能够在环境条件下产生半间距低于20 nm的密集高分辨率图案，可以使用硬掩膜图案堆叠和反应离子蚀刻(RIE)转移到硅衬底上。传输线的特征尺寸可以小到7纳米。可实现高达20毫米/秒的线性写入速度。与电子束光刻(EBL)不同，t-SPL不存在接近效应，避免了高能电子对敏感材料的衬底损伤。在书写过程中提供对图案区域的直接检查。覆盖图案没有额外的对准标记到预先存在的结构是t-SPL方法的另一个特点。现有的器件结构可以精确地定位在具有局部探针尖端的抗阻堆栈下，然后可以通过$\lt 5$纳米精度的覆盖对齐生成额外的目标结构。tSPL的另一个优势是能够生成3D图案。该过程可以控制生成深度精度为$\approx 1$ nm $(1 \sigma)$的3D结构。本文将讨论由tSPL制造的独特器件的例子。

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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2019 Pan Pacific Microelectronics Symposium (Pan Pacific)

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