Large-Area Nanopatterning Based on Field Alignment by the Microscale Metal Mask for the Etching Process

Jihye Lee; Jun Young Lee; Jong Souk Yeo

doi:10.1021/acsami.9b09730

Large-Area Nanopatterning Based on Field Alignment by the Microscale Metal Mask for the Etching Process

Jihye Lee, Jun Young Lee, Jong Souk Yeo

School of Integrated Technology

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

4 Citations (Scopus)

Abstract

Recently, researchers have dedicated efforts toward producing large-area nanostructures using advanced lithography techniques and state-of-the-art etching methods. However, these processes involve challenges such as the diffraction limit and an unintended etching profile. In this work, we demonstrate large-area nanopatterning on a silicon substrate using the microscale metal mask by meticulous optimization of the etching process. Around the vertex of a microscale metal mask, a locally induced electric field is generated by a bias voltage applied on a silicon mold. We utilize this field to change the trajectory of reactive ions and their effect flux, thus providing a controllable bowing effect. The results are analyzed by both numerical simulations and experiments. Based on the field alignment by the metal mask for the etching (FAME) process, we demonstrate the fabrication of 378 nm-size nanostructure patterns which translate to a size reduction of 63% from 1 μm-size mask patterns on a wafer by optimization of the processes. This is much higher than the undercut (â37%) usually achieved by a typical non-Bosch process under similar etching conditions. The optimized nanostructure is used as a mold for the transfer printing of nanostructure arrays on a flexible substrate to demonstrate that it enables the functionality of FAME-processed nanostructures.

Original language	English
Pages (from-to)	36177-36185
Number of pages	9
Journal	ACS Applied Materials and Interfaces
Volume	11
Issue number	39
DOIs	https://doi.org/10.1021/acsami.9b09730
Publication status	Published - 2019 Oct 2

Bibliographical note

Funding Information:
This research was supported by the Ministry of Trade Industry and Energy (MOTIE, project number 10080625) and the Korea Semiconductor Research Consortium (KSRC) support program for the development of future semiconductor devices and also under the "Mid-career Researcher Program" (NRF-2016R1A2B2014612) funded by the National Research Foundation (NRF).*%blankline%**%blankline%*

Funding Information:
This research was supported by the Ministry of Trade, Industry and Energy (MOTIE, project number 10080625) and the Korea Semiconductor Research Consortium (KSRC) support program for the development of future semiconductor devices and also under the “Mid-career Researcher Program” (NRF-2016R1A2B2014612) funded by the National Research Foundation (NRF).

Publisher Copyright:
Copyright © 2019 American Chemical Society.

All Science Journal Classification (ASJC) codes

Materials Science(all)

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10.1021/acsami.9b09730

Cite this

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title = "Large-Area Nanopatterning Based on Field Alignment by the Microscale Metal Mask for the Etching Process",

abstract = "Recently, researchers have dedicated efforts toward producing large-area nanostructures using advanced lithography techniques and state-of-the-art etching methods. However, these processes involve challenges such as the diffraction limit and an unintended etching profile. In this work, we demonstrate large-area nanopatterning on a silicon substrate using the microscale metal mask by meticulous optimization of the etching process. Around the vertex of a microscale metal mask, a locally induced electric field is generated by a bias voltage applied on a silicon mold. We utilize this field to change the trajectory of reactive ions and their effect flux, thus providing a controllable bowing effect. The results are analyzed by both numerical simulations and experiments. Based on the field alignment by the metal mask for the etching (FAME) process, we demonstrate the fabrication of 378 nm-size nanostructure patterns which translate to a size reduction of 63% from 1 μm-size mask patterns on a wafer by optimization of the processes. This is much higher than the undercut ({\^a}37%) usually achieved by a typical non-Bosch process under similar etching conditions. The optimized nanostructure is used as a mold for the transfer printing of nanostructure arrays on a flexible substrate to demonstrate that it enables the functionality of FAME-processed nanostructures.",

author = "Jihye Lee and Lee, {Jun Young} and Yeo, {Jong Souk}",

note = "Funding Information: This research was supported by the Ministry of Trade Industry and Energy (MOTIE, project number 10080625) and the Korea Semiconductor Research Consortium (KSRC) support program for the development of future semiconductor devices and also under the {"}Mid-career Researcher Program{"} (NRF-2016R1A2B2014612) funded by the National Research Foundation (NRF).*%blankline%**%blankline%* Funding Information: This research was supported by the Ministry of Trade, Industry and Energy (MOTIE, project number 10080625) and the Korea Semiconductor Research Consortium (KSRC) support program for the development of future semiconductor devices and also under the “Mid-career Researcher Program” (NRF-2016R1A2B2014612) funded by the National Research Foundation (NRF). Publisher Copyright: Copyright {\textcopyright} 2019 American Chemical Society.",

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N2 - Recently, researchers have dedicated efforts toward producing large-area nanostructures using advanced lithography techniques and state-of-the-art etching methods. However, these processes involve challenges such as the diffraction limit and an unintended etching profile. In this work, we demonstrate large-area nanopatterning on a silicon substrate using the microscale metal mask by meticulous optimization of the etching process. Around the vertex of a microscale metal mask, a locally induced electric field is generated by a bias voltage applied on a silicon mold. We utilize this field to change the trajectory of reactive ions and their effect flux, thus providing a controllable bowing effect. The results are analyzed by both numerical simulations and experiments. Based on the field alignment by the metal mask for the etching (FAME) process, we demonstrate the fabrication of 378 nm-size nanostructure patterns which translate to a size reduction of 63% from 1 μm-size mask patterns on a wafer by optimization of the processes. This is much higher than the undercut (â37%) usually achieved by a typical non-Bosch process under similar etching conditions. The optimized nanostructure is used as a mold for the transfer printing of nanostructure arrays on a flexible substrate to demonstrate that it enables the functionality of FAME-processed nanostructures.

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Large-Area Nanopatterning Based on Field Alignment by the Microscale Metal Mask for the Etching Process

Abstract

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