Enhancing detection sensitivity and molecular binding rate in plasmonic nanostructures

博士 === 國立清華大學 === 光電工程研究所 === 103 === In this dissertation, we report new methods to efficiently improve the detection limit of surface plasmon resonance in periodic metallic nanostructures by using small angle illumination, spectral integration analysis and dispersion curve of structure. We also pr...

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Main Authors: Lin, En-Hung, 林恩宏
Other Authors: Lee, Ming-Chang
Format: Others
Language:en_US
Published: 2014
Online Access:http://ndltd.ncl.edu.tw/handle/67975209787347614062
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spelling ndltd-TW-103NTHU51240092016-11-20T04:18:04Z http://ndltd.ncl.edu.tw/handle/67975209787347614062 Enhancing detection sensitivity and molecular binding rate in plasmonic nanostructures 增強電漿子奈米結構的偵測靈敏度與分子結合效率之研究 Lin, En-Hung 林恩宏 博士 國立清華大學 光電工程研究所 103 In this dissertation, we report new methods to efficiently improve the detection limit of surface plasmon resonance in periodic metallic nanostructures by using small angle illumination, spectral integration analysis and dispersion curve of structure. We also present the dynamic study of optical trapping of fluorescent molecules using high-density gold nanodisk arrays. In nanoslit structure, the large-area gold nanoslit arrays were fabricated by thermal-annealing template-stripping method. The slit width and period was 60nm and 500 nm. The small angle illumination induced a resonant coupling between surface plasmon mode and substrate mode. It increased ~2.24 times intensity sensitivity at 5.5° incident angle. The small-angle illumination also resulted in multiple resonant peaks. The spectral integration method integrated all changes near the resonant peaks and increased the signal to noise ratio about 5 times as compared to single-wavelength intensity analysis. In nanohole structure, the large-area gold nanohole arrays were fabricated by thermal-annealing template-stripping method. The hole diameter and period was 180nm and 600nm. The (±1,∓1) surface mode which has higher angular RIU sensitivity of surface plasmon resonance improvement ~440 deg/RIU by change angle of light incident. The flat dispersion curve of (±1,∓1) surface mode was observed by large angle illumination due to electric field localized in hole cavity. It increased ~6.2 times than (±1,0) surface mode near 0° and also increased ~2.3 and ~4.5 times than prism coupler-based SPR sensor of angular RIU sensitivity at 630nm and 850nm, respectively. In gold nanodisk strucutre, the gold nanodisks were fabricated by electron beam lithography with a diameter of 500 nm and a period of 1 μm. Dark-field illumination showed ∼15 times enhancement of fluorescence near edges of nanodisks. Such enhanced near-field generated an optical trapping force of ∼10 fN under 3.58 × 103 W/m2 illumination intensity as calculated from the Brownian motions of 590 nm polystyrene beads. Kinetic observation of thiolated DNA modified with Cy5 dye showed different binding rates of DNA under different illumination intensity. The binding rate increased from 2.14 × 103 s−1 (I = 0.7 × 103 W/m2) to 1.15 × 105 s−1 (I = 3.58 × 103 W/m2). Based on above methods, it efficiently improves the intensity and angular sensitivity of surface plasmon resonance such as small angle incidence, spectral integration and dispersion curve of strucutre. Furthermore, gold nanodisks also efficiently improve both detection limit and interaction time. Lee, Ming-Chang Wei, Pei-Kuen 李明昌 魏培坤 2014 學位論文 ; thesis 81 en_US
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language en_US
format Others
sources NDLTD
description 博士 === 國立清華大學 === 光電工程研究所 === 103 === In this dissertation, we report new methods to efficiently improve the detection limit of surface plasmon resonance in periodic metallic nanostructures by using small angle illumination, spectral integration analysis and dispersion curve of structure. We also present the dynamic study of optical trapping of fluorescent molecules using high-density gold nanodisk arrays. In nanoslit structure, the large-area gold nanoslit arrays were fabricated by thermal-annealing template-stripping method. The slit width and period was 60nm and 500 nm. The small angle illumination induced a resonant coupling between surface plasmon mode and substrate mode. It increased ~2.24 times intensity sensitivity at 5.5° incident angle. The small-angle illumination also resulted in multiple resonant peaks. The spectral integration method integrated all changes near the resonant peaks and increased the signal to noise ratio about 5 times as compared to single-wavelength intensity analysis. In nanohole structure, the large-area gold nanohole arrays were fabricated by thermal-annealing template-stripping method. The hole diameter and period was 180nm and 600nm. The (±1,∓1) surface mode which has higher angular RIU sensitivity of surface plasmon resonance improvement ~440 deg/RIU by change angle of light incident. The flat dispersion curve of (±1,∓1) surface mode was observed by large angle illumination due to electric field localized in hole cavity. It increased ~6.2 times than (±1,0) surface mode near 0° and also increased ~2.3 and ~4.5 times than prism coupler-based SPR sensor of angular RIU sensitivity at 630nm and 850nm, respectively. In gold nanodisk strucutre, the gold nanodisks were fabricated by electron beam lithography with a diameter of 500 nm and a period of 1 μm. Dark-field illumination showed ∼15 times enhancement of fluorescence near edges of nanodisks. Such enhanced near-field generated an optical trapping force of ∼10 fN under 3.58 × 103 W/m2 illumination intensity as calculated from the Brownian motions of 590 nm polystyrene beads. Kinetic observation of thiolated DNA modified with Cy5 dye showed different binding rates of DNA under different illumination intensity. The binding rate increased from 2.14 × 103 s−1 (I = 0.7 × 103 W/m2) to 1.15 × 105 s−1 (I = 3.58 × 103 W/m2). Based on above methods, it efficiently improves the intensity and angular sensitivity of surface plasmon resonance such as small angle incidence, spectral integration and dispersion curve of strucutre. Furthermore, gold nanodisks also efficiently improve both detection limit and interaction time.
author2 Lee, Ming-Chang
author_facet Lee, Ming-Chang
Lin, En-Hung
林恩宏
author Lin, En-Hung
林恩宏
spellingShingle Lin, En-Hung
林恩宏
Enhancing detection sensitivity and molecular binding rate in plasmonic nanostructures
author_sort Lin, En-Hung
title Enhancing detection sensitivity and molecular binding rate in plasmonic nanostructures
title_short Enhancing detection sensitivity and molecular binding rate in plasmonic nanostructures
title_full Enhancing detection sensitivity and molecular binding rate in plasmonic nanostructures
title_fullStr Enhancing detection sensitivity and molecular binding rate in plasmonic nanostructures
title_full_unstemmed Enhancing detection sensitivity and molecular binding rate in plasmonic nanostructures
title_sort enhancing detection sensitivity and molecular binding rate in plasmonic nanostructures
publishDate 2014
url http://ndltd.ncl.edu.tw/handle/67975209787347614062
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