Scalable digital atomic precision lithography

E. Fuchs, James H. G. Owen, Afshin Alipour, Emma Fowler, S. Moheimani, J. N. Randall
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Abstract

Current lithographic techniques are limited to a resolution of a few nm with poor relative precision. Scanning Tunneling Microscope (STM) based lithography[1], removes H from H-passivated Si 2x1 (100) by a mode distinct from usual imaging. This technique is generally called Hydrogen Depassivation Lithography (HDL) and since it scans a beam of electrons around on a surface exposing a resist, it is a form of E-beam Lithography. The HDL approach is not effective with standard resists and, at present, has only a limited number of pattern transfer methods. The two primary ones are patterning 2D delta doped Si devices for solid state quantum devices and selective Atomic Layer Deposition metal oxides that can be used as hard etch masks. However, electron stimulated desorption of atoms and molecules is a fairly generic process and its use can be anticipated on a wide variety of substrates. Sub-nm resolution (0.768 nm) has been demonstrated and used for numerous research purposes, such as dopant positioning for quantum devices[2]. While sub-nm resolution is easily obtainable with standard Ultra-High Vacuum (UHV) STMs, the repeatability and accuracy of the patterning has limited its applications. In this paper we report on progress to dramatically scale HDL’s throughput while maintaining sub-nm resolution.
可伸缩数字原子精密光刻
目前的光刻技术仅限于几纳米的分辨率,相对精度较差。基于扫描隧道显微镜(STM)的光刻[1],通过不同于通常成像的模式从H钝化Si 2x1(100)中去除H。这种技术通常被称为氢脱钝化光刻(HDL),由于它扫描表面上的电子束,从而暴露出抗蚀剂,因此它是电子束光刻的一种形式。高密度脂蛋白方法对标准电阻不有效,目前只有有限数量的模式转移方法。两个主要的方向是为固态量子器件和可作为硬蚀刻掩模的选择性原子层沉积金属氧化物绘制二维δ掺杂Si器件的图像化。然而,电子刺激原子和分子的解吸是一个相当普遍的过程,它的使用可以预期在各种各样的底物。亚纳米分辨率(0.768 nm)已被证明并用于许多研究目的,如量子器件的掺杂剂定位[2]。虽然标准的超高真空(UHV) STMs很容易获得亚纳米分辨率,但图案的可重复性和准确性限制了其应用。在本文中,我们报告了在保持亚纳米分辨率的同时显着扩展HDL吞吐量的进展。
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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