• Title/Summary/Keyword: Nano Imprinting Lithography

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State of the art and technological trend for the nano-imprinting lithography equipment (나노 임프린팅 리소그래피 장비의 기술개발 동향)

  • 이재종;최기봉;정광조
    • Proceedings of the Korean Society of Precision Engineering Conference
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    • 2003.06a
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    • pp.196-198
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    • 2003
  • Classical lithography in semiconductor employs stepper technologies. Limits of this technology are clearly seen at structures below 100nm. Nano-imprinting lithography is a new method for generating patterns in submicron range at reasonable cost. In order to manufacture nano-imprinting lithography(NIL) equipment, several NIL manufacturers have been developing key technologies for realization of nano-imprinting process, recently. In this paper, we've been describe state-of-the-art and technology trends for nano-imprinting lithography equipments.

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Fabrication of Functional ZnO Nano-particles Dispersion Resin Pattern Through Thermal Imprinting Process (ZnO 나노 입자 분산 레진의 thermal imprinting 공정을 통한 기능성 패턴 제작)

  • Kwon, Moo-Hyun;Lee, Heon
    • Journal of the Korean Society for Precision Engineering
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    • v.28 no.12
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    • pp.1419-1424
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    • 2011
  • Nanoimprint lithography is a next generation lithography technology, which enables to fabricate nano to micron-scale patterns through simple and low cost process. Nanoimprint lithography has been applied in various industry fields such as light emitting diodes, solar cells and display. Functional patterns, including anti-reflection moth-eye pattern, photonic crystal pattern, fabricated by nanoimprint lithography are used to improve overall efficiency of devices in that fields. For these reasons, in this study, sub-micron-scaled functional patterns were directly fabricated on Si and glass substrates by thermal imprinting process using ZnO nano-particles dispersion resin. Through the thermal imprinting process, arrays of sub-micron-scaled pillar and hole patterns were successfully fabricated on the Si and glass substrates. And then, the topography, components and optical property of the imprinted ZnO nano-particles/resin patterns are characterized by Scanning Electron Microscope, Energy-dispersive X-ray spectroscopy and UV-vis spectrometer, respectively.

Nano-mold fabrication for imprinting lithography (나도 Imprinting 을 위한 몰드 제작에 관한 연구)

  • Lee, Jin-Hyung;Lim, Hyun-Uoo;Kim, Tae-Gon;Lee, Seung-Seoup;Park, Jin-Goo;Lee, Eun-Kyu;Kim, Yang-Sun;Han, Chang-Su
    • Proceedings of the KSME Conference
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    • 2003.04a
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    • pp.1073-1077
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    • 2003
  • This study aims to investigate the fabrication process of nano silicon mold using electron beam lithography (EBL) to generate the nanometer level patterns by nano-imprinting technology. the nano-patterned mold including 100mm pattern size has been fabricated by EBL with different doses ranged from 22 to 38 ${\mu}C/cm^2$ on silicon using the conventional polymethylmetharcylate(PMMA) resist. The silicon mold is fabricated with various patterns such as circles, rectangles, crosses, oblique lines and mixed forms, The effect of dosage on pattern density in EBL is discussed based on SEM (Scannning Electron Microscopy) analysis of fabricated molds. The mold surface is modified by hydrophobic fluorocarbon (FC) thin films to avoid the stiction during nano-imprinting process.

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Sub 150nm Soft-Lithography using the monomer based thermally curable resin (Monomer based thermally curable resin을 이용한 150nm 급 Soft-Lithography)

  • Yang K.Y.;Hong S.H.;Lee H.
    • Proceedings of the Korean Society of Precision Engineering Conference
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    • 2005.06a
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    • pp.676-679
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    • 2005
  • Nano imprint Lithography (NIL) is regarded as one of the next-generation lithography technologies with EUV lithography, immersion lithography, Laser interference lithography. Because a Si wafer stamp and a quartz stamp, used to imprinting usually are very expensive and easily broken, it is suggested that master stamp is duplicated by PDMS and the PDMS stamp uses to imprint .For using the PDMS stamp, a thermally curable monomer resin was used for the imprinting process to lower pressure and temperature. As a result, NIL patterns were successfully fabricated.

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Fabrications of nano-sized patterns using bi-layer UV Nano imprint Lithography (UV NIL을 이용한 Lift-off가 용이한 패턴 형성 연구)

  • Yang K.Y.;Hong S.H.;Lee H.
    • Proceedings of the Korean Society of Precision Engineering Conference
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    • 2005.06a
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    • pp.1489-1492
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    • 2005
  • Compared to other nano-patterning techniques, Nano imprint Lithography (NIL) has some advantages of high throughput and low process cost. To imprint low temperature and pressure, UV Nano imprint Lithography, which using the monomer based UV curable resin is suggested. Because fabrication of high fidelity pattern on topographical substrate is difficult, bi-layer Nano imprint lithography, which are consist of easily removable under-layer and imprinted pattern, is being used. If residual layer is not remained after imprinting, and under-layer is removed by oxygen RIE etching, we might be able to fabricate the bi-layer pattern for easy lift-off process.

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Fabrication of a 17inch Area Size Nano-Wire Grid using Roll-to-Roll UV Nano-Imprinting Lithography (Roll-to-Roll UV 나노 임프린팅 리소그래피에 의한 대면적 17인치의 나노 와이어 그리드의 제작)

  • Huh, Jong-Wook;Nam, Su-Yong
    • Journal of the Korean Graphic Arts Communication Society
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    • v.29 no.3
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    • pp.17-30
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    • 2011
  • The polarizer is an important optical element used in a variety of applications. Nano-wire grid polarizers in the form of sub-wavelength metallic gratings are an attractive alternative to conventional polarizers, because they provide high extinction ratio. This study has been carried out to fabrication of the 17inch area size nano-wire grid polarizer(NWGP) The master for NWGPs with a pitch of 200nm and the area size $730mm{\times}450mm$ were fabricated using laser interference lithography and aluminum sputtering and wet etching. And The NWGP fabrication process was using by the Roll to-Roll UV imprinting and was applied to flexible PET film. The results were a transmission of light (Tp) 46.7%, reflectance (Rs) 40.1% and Extinction ratio of above 16 for the visible light range.

Fabrication of Metallic Nano-filter Using UV-Imprinting Process (UV 임프린팅 공정을 이용한 금속막 필터제작)

  • Noh Cheol Yong;Lee Namseok;Lim Jiseok;Kim Seok-min;Kang Shinill
    • Proceedings of the Korean Society for Technology of Plasticity Conference
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    • 2005.05a
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    • pp.237-240
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    • 2005
  • The demand of micro electrical mechanical system (MEMS) bio/chemical sensor is rapidly increasing. To prevent the contamination of sensing area, a filtration system is required in on-chip total analyzing MEMS bio/chemical sensor. A nano-filter was mainly applied in some application detecting submicron feature size bio/chemical products such as bacteria, fungi and so on. We suggested a simple nano-filter fabrication process based on replication process. The mother pattern was fabricated by holographic lithography and reactive ion etching process, and the replication process was carried out using polymer mold and UV-imprinting process. Finally the nano-filter is obtained after removing the replicated part of metal deposited replica. In this study, as a practical example of the suggested process, a nano-dot array was replicated to fabricate nano-filter fur bacteria sensor application.

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Fabrication of Metallic Nano-Filter Using UV-Imprinting Process (UV 임프린팅 공정을 이용한 금속막 필터제작)

  • Noh Cheol Yong;Lee Namseok;Lim Jiseok;Kim Seok-min;Kang Shinill
    • Transactions of Materials Processing
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    • v.14 no.5 s.77
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    • pp.473-476
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    • 2005
  • The demand of on-chip total analyzing system with MEMS (micro electro mechanical system) bio/chemical sensor is rapidly increasing. In on-chip total analyzing system, to detect the bio/chemical products with submicron feature size, a filtration system with nano-filter is required. One of the conventional methods to fabricate nano-filter is to use direct patterning or RIE (reactive ion etching). However, those procedures are very costly and are not suitable fur mass production. In this study, we suggested new fabrication method for a nano-filter based on replication process, which is simple and low cost process. After the Si master was fabricated by laser interference lithography and reactive ion etching process, the polymeric mold was replicated by UV-imprint process. Metallic nano-filter was fabricated after removing the polymeric part of metal deposited polymeric mold. Finally, our fabrication method was applied to metallic nano-filter with $1{\mu}m$ pitch size and $0.4{\mu}m$ hole size for bacteria sensor application.