Fresnel diffraction lithography

Author:

Jiang Zhong-Jun,He Wei,Chen Jing-Wei,Luo Dan-Yang,Yang Fan,Jiang Kai,Wang Liang,

Abstract

Lithography plays a vital important role in modern information technologies. Patterning on a nanoscale in a handy way is highly desired for both scientific and industrial purposes. In this work, we propose a convenient nanolithography method based on Fresnel diffraction patterns. We start with the explanation of the “dense-inside-sparse-outside” Fresnel diffraction fringes resulting from the apertures of finite extent, by using the fast Fourier transform algorithm through appropriately choosing the number of uniformly spaced samples. Moderately focusing the diffraction patterns via high-numerical-aperture objectives ( the method is termed the “Fresnel diffraction lithography”), the rotationally symmetric patterns with a minimum feature size of ~190 nm, and the scanning lines with a width of ~350 nm are realized, respectively, The calculation using vectorial diffraction theory suggests a better resolution when perfectly focused. This method shows good tolerance to defocus and does not require complex lens combinations or micro/nano-diffraction optical elements, Therefore, this method can find some applications in widespread areas, e.g. functional metasurfaces, as a novel and low-cost nano-patterning technology with sub-wavelength resolution and high flexibility.

Publisher

Acta Physica Sinica, Chinese Physical Society and Institute of Physics, Chinese Academy of Sciences

Subject

General Physics and Astronomy

Reference26 articles.

1. Menon R, Patel A, Gil D, Smith H I 2005 Mater. Today 8 26

2. Xu K, Qin J, Wang L 2021 Opt. Lett. 46 5185

3. Sanders D P 2010 Chem. Rev. 110 321

4. School J S, Schenau K I, Valentin C, Migura S 2015 Proc. SPIE 9422, Extreme Ultraviolet (EUV) Lithography VI San Jose, California, United States, March 16, 2015 p94221F

5. Chen Y F 2015 Microelectron. Eng. 135 57

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