Fabrication of nanogap structures through spatially shaped femtosecond laser modification with the assistance of wet chemical etching

Shipeng Zhou; Xiaowei Li; Ji Huang; Zhipeng Wang; Yang Liu; Shuai Gao; Zhijie Xu; Lan Jiang

doi:10.1364/OL.431385

Fabrication of nanogap structures through spatially shaped femtosecond laser modification with the assistance of wet chemical etching

Shipeng Zhou, Xiaowei Li^*, Ji Huang, Zhipeng Wang, Yang Liu, Shuai Gao, Zhijie Xu, Lan Jiang

^*Corresponding author for this work

School of Mechanical Engineering

Research output: Contribution to journal › Article › peer-review

4 Citations (Scopus)

Abstract

Fabricating nanostructures with an extremely small feature size through a near-infrared femtosecond laser is a considerable challenge. In this Letter, we report a flexible, facile, and mask-free method that enables the formation of nanogap structures with a controllable size on silicon. This method involves spatially shaped femtosecond laser single-pulse modification assisted with chemical etching. Nanogaps obtained after etching can be divided into two categories, namely a ring dimer with a nanogap (type I) and Crack-nanogap (type II). The nanogap between the ring dimer could be reduced to 68 nm with a gradual increase in the laser fluence. For the Crack-nanogap obtained through crack propagation induced by stress release during a wet etching process, the smallest gap size is approximately 9 nm.

Original language	English
Pages (from-to)	3560-3563
Number of pages	4
Journal	Optics Letters
Volume	46
Issue number	15
DOIs	https://doi.org/10.1364/OL.431385
Publication status	Published - 1 Aug 2021

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title = "Fabrication of nanogap structures through spatially shaped femtosecond laser modification with the assistance of wet chemical etching",

abstract = "Fabricating nanostructures with an extremely small feature size through a near-infrared femtosecond laser is a considerable challenge. In this Letter, we report a flexible, facile, and mask-free method that enables the formation of nanogap structures with a controllable size on silicon. This method involves spatially shaped femtosecond laser single-pulse modification assisted with chemical etching. Nanogaps obtained after etching can be divided into two categories, namely a ring dimer with a nanogap (type I) and Crack-nanogap (type II). The nanogap between the ring dimer could be reduced to 68 nm with a gradual increase in the laser fluence. For the Crack-nanogap obtained through crack propagation induced by stress release during a wet etching process, the smallest gap size is approximately 9 nm.",

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T1 - Fabrication of nanogap structures through spatially shaped femtosecond laser modification with the assistance of wet chemical etching

AU - Zhou, Shipeng

AU - Li, Xiaowei

AU - Huang, Ji

AU - Wang, Zhipeng

AU - Liu, Yang

AU - Gao, Shuai

AU - Xu, Zhijie

AU - Jiang, Lan

PY - 2021/8/1

Y1 - 2021/8/1

N2 - Fabricating nanostructures with an extremely small feature size through a near-infrared femtosecond laser is a considerable challenge. In this Letter, we report a flexible, facile, and mask-free method that enables the formation of nanogap structures with a controllable size on silicon. This method involves spatially shaped femtosecond laser single-pulse modification assisted with chemical etching. Nanogaps obtained after etching can be divided into two categories, namely a ring dimer with a nanogap (type I) and Crack-nanogap (type II). The nanogap between the ring dimer could be reduced to 68 nm with a gradual increase in the laser fluence. For the Crack-nanogap obtained through crack propagation induced by stress release during a wet etching process, the smallest gap size is approximately 9 nm.

AB - Fabricating nanostructures with an extremely small feature size through a near-infrared femtosecond laser is a considerable challenge. In this Letter, we report a flexible, facile, and mask-free method that enables the formation of nanogap structures with a controllable size on silicon. This method involves spatially shaped femtosecond laser single-pulse modification assisted with chemical etching. Nanogaps obtained after etching can be divided into two categories, namely a ring dimer with a nanogap (type I) and Crack-nanogap (type II). The nanogap between the ring dimer could be reduced to 68 nm with a gradual increase in the laser fluence. For the Crack-nanogap obtained through crack propagation induced by stress release during a wet etching process, the smallest gap size is approximately 9 nm.

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JO - Optics Letters

JF - Optics Letters

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ER -

Fabrication of nanogap structures through spatially shaped femtosecond laser modification with the assistance of wet chemical etching

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