Solid-state electrochemical stamping of functional metallic nanostructures

Keng Hsu; Peter Schultz; Placid Mathew Ferreira; Nicholas Fang

doi:10.1109/NANO.2007.4601162

Solid-state electrochemical stamping of functional metallic nanostructures

Keng Hsu, Peter Schultz, Placid Mathew Ferreira, Nicholas Fang

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

Abstract

A new approach of directly patterning metal at nano-scale with excellent dimensional resolution and flexibility is introduced for fabrication of functional nano-structures. This technique is based on the solid-state electrochemical dissolution of a metallic substrate at its contact with a pre-patterned surface of a solid electrolyte tool, and the subsequent formation of the complimentary pattern on the metal substrate as the solid electrolyte etches through the metal layer. Our results demonstrate repeatable and high-fidelity patterning of metal structures with a wide dimension range (20μm to 50nm). As this process is carried out in ambient environment and does not require wet chemicals, its potential for use as a simple and yet high-throughput metal patterning technique offers a highly competitive approach to fabricating functional structures and devices such as chemical sensors and photonic devices.

Original language	English (US)
Title of host publication	2007 7th IEEE International Conference on Nanotechnology - IEEE-NANO 2007, Proceedings
Pages	162-165
Number of pages	4
DOIs	https://doi.org/10.1109/NANO.2007.4601162
State	Published - 2007
Event	2007 7th IEEE International Conference on Nanotechnology - IEEE-NANO 2007 - Hong Kong, China Duration: Aug 2 2007 → Aug 5 2007

Publication series

Name	2007 7th IEEE International Conference on Nanotechnology - IEEE-NANO 2007, Proceedings

Other

Other	2007 7th IEEE International Conference on Nanotechnology - IEEE-NANO 2007
Country/Territory	China
City	Hong Kong
Period	8/2/07 → 8/5/07

Keywords

Electrochemistry
Nanoimprint lithography
Nanophotonics
Solid state ionics
Surface enhanced raman spectroscopy

ASJC Scopus subject areas

Electrical and Electronic Engineering
Atomic and Molecular Physics, and Optics

Online availability

10.1109/NANO.2007.4601162

Library availability

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Cite this

Hsu, K., Schultz, P., Ferreira, P. M., & Fang, N. (2007). Solid-state electrochemical stamping of functional metallic nanostructures. In 2007 7th IEEE International Conference on Nanotechnology - IEEE-NANO 2007, Proceedings (pp. 162-165). [4601162] (2007 7th IEEE International Conference on Nanotechnology - IEEE-NANO 2007, Proceedings). https://doi.org/10.1109/NANO.2007.4601162

Solid-state electrochemical stamping of functional metallic nanostructures. / Hsu, Keng; Schultz, Peter; Ferreira, Placid Mathew et al.
2007 7th IEEE International Conference on Nanotechnology - IEEE-NANO 2007, Proceedings. 2007. p. 162-165 4601162 (2007 7th IEEE International Conference on Nanotechnology - IEEE-NANO 2007, Proceedings).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

Hsu, K, Schultz, P, Ferreira, PM & Fang, N 2007, Solid-state electrochemical stamping of functional metallic nanostructures. in 2007 7th IEEE International Conference on Nanotechnology - IEEE-NANO 2007, Proceedings., 4601162, 2007 7th IEEE International Conference on Nanotechnology - IEEE-NANO 2007, Proceedings, pp. 162-165, 2007 7th IEEE International Conference on Nanotechnology - IEEE-NANO 2007, Hong Kong, China, 8/2/07. https://doi.org/10.1109/NANO.2007.4601162

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abstract = "A new approach of directly patterning metal at nano-scale with excellent dimensional resolution and flexibility is introduced for fabrication of functional nano-structures. This technique is based on the solid-state electrochemical dissolution of a metallic substrate at its contact with a pre-patterned surface of a solid electrolyte tool, and the subsequent formation of the complimentary pattern on the metal substrate as the solid electrolyte etches through the metal layer. Our results demonstrate repeatable and high-fidelity patterning of metal structures with a wide dimension range (20μm to 50nm). As this process is carried out in ambient environment and does not require wet chemicals, its potential for use as a simple and yet high-throughput metal patterning technique offers a highly competitive approach to fabricating functional structures and devices such as chemical sensors and photonic devices.",

keywords = "Electrochemistry, Nanoimprint lithography, Nanophotonics, Solid state ionics, Surface enhanced raman spectroscopy",

author = "Keng Hsu and Peter Schultz and Ferreira, {Placid Mathew} and Nicholas Fang",

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AU - Schultz, Peter

AU - Ferreira, Placid Mathew

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N2 - A new approach of directly patterning metal at nano-scale with excellent dimensional resolution and flexibility is introduced for fabrication of functional nano-structures. This technique is based on the solid-state electrochemical dissolution of a metallic substrate at its contact with a pre-patterned surface of a solid electrolyte tool, and the subsequent formation of the complimentary pattern on the metal substrate as the solid electrolyte etches through the metal layer. Our results demonstrate repeatable and high-fidelity patterning of metal structures with a wide dimension range (20μm to 50nm). As this process is carried out in ambient environment and does not require wet chemicals, its potential for use as a simple and yet high-throughput metal patterning technique offers a highly competitive approach to fabricating functional structures and devices such as chemical sensors and photonic devices.

AB - A new approach of directly patterning metal at nano-scale with excellent dimensional resolution and flexibility is introduced for fabrication of functional nano-structures. This technique is based on the solid-state electrochemical dissolution of a metallic substrate at its contact with a pre-patterned surface of a solid electrolyte tool, and the subsequent formation of the complimentary pattern on the metal substrate as the solid electrolyte etches through the metal layer. Our results demonstrate repeatable and high-fidelity patterning of metal structures with a wide dimension range (20μm to 50nm). As this process is carried out in ambient environment and does not require wet chemicals, its potential for use as a simple and yet high-throughput metal patterning technique offers a highly competitive approach to fabricating functional structures and devices such as chemical sensors and photonic devices.

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KW - Nanoimprint lithography

KW - Nanophotonics

KW - Solid state ionics

KW - Surface enhanced raman spectroscopy

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Y2 - 2 August 2007 through 5 August 2007

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Solid-state electrochemical stamping of functional metallic nanostructures

Abstract

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Keywords

ASJC Scopus subject areas

Online availability

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