Your search keyword '"SeungWoo Lee"' showing total 4 results

1. Sub-100 nm gold nanohole-enhanced Raman scattering on flexible PDMS sheets

Author

Geumhye Jeon, Seunghyun Lee, Sang Gu Yim, Ho Young Kim, Seungwoo Lee, Seung Yun Yang, Minseok Kwak, Hee Jin Jeong, and Andry Ongko

Subjects

Materials science, Infrared spectroscopy, Bioengineering, Nanotechnology, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, chemistry.chemical_compound, symbols.namesake, General Materials Science, Electrical and Electronic Engineering, Lithography, chemistry.chemical_classification, Plasma etching, Polydimethylsiloxane, Mechanical Engineering, General Chemistry, Polymer, 021001 nanoscience & nanotechnology, 0104 chemical sciences, chemistry, Mechanics of Materials, symbols, Surface modification, 0210 nano-technology, Raman spectroscopy, Raman scattering

Abstract

Surface-enhanced Raman spectroscopy (SERS) is a highly sensitive vibrational spectroscopy technique enabling detection of multiple analytes at the molecular level in a nondestructive and rapid manner. In this work, we introduce a new approach to fabricate deep subwavelength-scaled (sub-100 nm) metallic nanohole arrays (quasi-3D metallic nanoholes) on flexible and highly efficient SERS substrates. Target structures have been fabricated using a two-step process consisting of (i) direct pattern transfer of spin-coated polymer films onto polydimethylsiloxane (PDMS) substrates by plasma etching with transferred anodic aluminum oxide masks, and (ii) producing SERS-active substrates by functionalization of the etched polymeric films followed by Au deposition. Such an all-dry, top-down lithographic approach enables on-demand patterning of SERS-active metallic nanoholes with high structural fidelity even onto flexible and stretchable substrates, thus making possible multiple sensing modes in a versatile fashion. For example, metallic nanoholes on flexible PDMS substrates are highly amenable to their integration with curved glass sticks, which can be used in optical fiber-integrated SERS systems. Au surfaces immobilized by probe DNA molecules show a selective enhancement of Raman scattering with Cy5-labeled complementary DNA (as compared to flat Au surfaces), demonstrating the potential of using the quasi-3D Au nanohole arrays for bio-sensing applications.

Published

2016

2. Enhanced ionic conductivity of AgI nanowires/AAO composites fabricated by a simple approach

Author

Lifeng Liu, Guanghui Rao, Jingbo Li, Marin Alexe, Seungwoo Lee, Woo Lee, JaeJong Lee, Weiya Zhou, and Ulrich Gösele

Subjects

Materials science, Scanning electron microscope, Mechanical Engineering, Silver iodide, Nanowire, Bioengineering, General Chemistry, Conductivity, chemistry.chemical_compound, Differential scanning calorimetry, chemistry, Mechanics of Materials, Electrical resistivity and conductivity, Ionic conductivity, General Materials Science, Crystallite, Electrical and Electronic Engineering, Composite material

Abstract

AgI nanowires/anodic aluminum oxide ( AgI NWs/AAO) composites have been fabricated by a simple approach, which involves the thermal melting of AgI powders on the surface of the AAO membrane, followed by the infiltration of the molten AgI inside the nanochannels. As-prepared AgI nanowires have corrugated outer surfaces and are polycrystalline according to scanning electron microscopy (SEM) and transmission electron microscopy (TEM) observations. X-ray diffraction (XRD) shows that a considerable amount of 7H polytype AgI exists in the composites, which is supposed to arise from the interfacial interactions between the embedded AgI and the alumina. AC conductivity measurements for the AgI nanowires/AAO composites exhibit a notable conductivity enhancement by three orders of magnitude at room temperature compared with that of pristine bulk AgI. Furthermore, a large conductivity hysteresis and abnormal conductivity transitions were observed in the temperature-dependent conductivity measurements, from which an ionic conductivity as high as 8.0 x 10(2) Omega(-1) cm(-1) was obtained at around 70 degrees C upon cooling. The differential scanning calorimetry (DSC) result demonstrates a similar phase transition behavior as that found in the AC conductivity measurements. The enhanced ionic conductivity, as well as the abnormal phase transitions, can be explained in terms of the existence of the highly conducting 7H polytype AgI and the formation of well-defined conduction paths in the composites.

Published

2011

3. Control of density and LSPR of Au nanoparticles on graphene.

Author

Seungwoo Lee, Min hyung Lee, Hyeon-jin Shin, and Dukyun Choi

Subjects

*SURFACE plasmon resonance, *GOLD nanoparticles, *GRAPHENE, *REDUCTION potential, *SURFACE energy, *BIOCHEMICAL substrates, *OPTOELECTRONICS

Abstract

In this study, we introduce the tunable density and localized surface plasmon resonance (LSPR) of plasmonic gold (Au) nanoparticles which were formed on monolayer graphene at room temperature, based on the difference of the reduction potential between graphene and the Au3+ precursor. The size of the Au nanoparticles was ∼40 nm, which is very desirable to provide an optical enhancement effect by LSPR in the full visible range. It is demonstrated that the density of the Au nanoparticles was modulated by the surface energy of the graphene on the substrate as well as the concentration of the Au3+ precursor. Furthermore, the cycle number of the reduction process strongly affected the distribution of the nanoparticle size and their optical properties. The LSPR of the plasmonic Au nanoparticles was red-shifted from 560 to 620 nm and its full width at half maximum broadened as the Au3+ precursor concentration was increased and the cyclic reduction process progressed. Based on the optical enhancement of the plasmonic Au nanoparticles and the extraordinary physical characteristics of graphene, the Au/graphene assembly may offer a promising optoelectronic platform for next-generation flexible optical electronics or biosensors. [ABSTRACT FROM AUTHOR]

Published

2013

4. Sub-100 nm gold nanohole-enhanced Raman scattering on flexible PDMS sheets.

Author

Seunghyun Lee, Andry Ongko, Ho Young Kim, Sang-Gu Yim, Geumhye Jeon, Hee Jin Jeong, Seungwoo Lee, Minseok Kwak, and Seung Yun Yang

Subjects

RAMAN scattering, NUCLEIC acids, LIGHT scattering, INELASTIC scattering, BIOMOLECULES

Abstract

Surface-enhanced Raman spectroscopy (SERS) is a highly sensitive vibrational spectroscopy technique enabling detection of multiple analytes at the molecular level in a nondestructive and rapid manner. In this work, we introduce a new approach to fabricate deep subwavelength-scaled (sub-100 nm) metallic nanohole arrays (quasi-3D metallic nanoholes) on flexible and highly efficient SERS substrates. Target structures have been fabricated using a two-step process consisting of (i) direct pattern transfer of spin-coated polymer films onto polydimethylsiloxane (PDMS) substrates by plasma etching with transferred anodic aluminum oxide masks, and (ii) producing SERS-active substrates by functionalization of the etched polymeric films followed by Au deposition. Such an all-dry, top-down lithographic approach enables on-demand patterning of SERS-active metallic nanoholes with high structural fidelity even onto flexible and stretchable substrates, thus making possible multiple sensing modes in a versatile fashion. For example, metallic nanoholes on flexible PDMS substrates are highly amenable to their integration with curved glass sticks, which can be used in optical fiber-integrated SERS systems. Au surfaces immobilized by probe DNA molecules show a selective enhancement of Raman scattering with Cy5-labeled complementary DNA (as compared to flat Au surfaces), demonstrating the potential of using the quasi-3D Au nanohole arrays for bio-sensing applications. [ABSTRACT FROM AUTHOR]

Published

2016