Turning on Resonant SERRS Using the Chromophore−Plasmon Coupling Created by Host−Guest Complexation at a Plasmonic Nanoarray

Witlicki, Edward H.; Andersen, Sissel; Hansen, Stinne Wessel; Jeppesen, Jan O.; Wong, E.W.M.; Jensen, Lasse; Flood, Amar H.

doi:10.1021/ja910155b

Cited by 45 publications

(50 citation statements)

References 165 publications

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“…5D, their extinction peaks overlap the absorption peak of the azobenzene molecule. Because coupling strength has been found to be strongly dependent on the spectral overlap between the molecular and plasmonic resonances (33,34), there is, accordingly, a large coupling strength between azobenzene and the plasmonic resonance of both Ag nanospheres and nanowires. However, Ag nanoprisms give a peak located at 820 nm, which does not overlap with the absorption peak of azobenzene.…”

Section: Resultsmentioning

confidence: 99%

Using silver nanowire antennas to enhance the conversion efficiency of photoresponsive DNA nanomotors

Yuan

Zhang²,

Chen³

et al. 2011

Proc. Natl. Acad. Sci. U.S.A.

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Plasmonic near-field coupling can induce the enhancement of photoresponsive processes by metal nanoparticles. Advances in nanostructured metal synthesis and theoretical modeling have kept surface plasmons in the spotlight. Previous efforts have resulted in significant intensity enhancement of organic dyes and quantum dots and increased absorption efficiency of optical materials used in solar cells. Here, we report that silver nanostructures can enhance the conversion efficiency of an interesting type of photosensitive DNA nanomotor through coupling with incorporated azobenzene moieties. Spectral overlap between the azobenzene absorption band and plasmonic resonances of silver nanowires increases light absorption of photon-sensitive DNA motor molecules, leading to 85% close-open conversion efficiency. The experimental results are consistent with our theoretical calculations of the electric field distribution. This enhanced conversion of DNA nanomotors holds promise for the development of new types of molecular nanodevices for light manipulative processes and solar energy harvesting.energy conversion | localized surface plasmon | photo-driven nanomotor P lants harvest solar energy by photosynthesis, in which photosensitive biomolecules absorb energy from sunlight and convert it into chemical energy. Human beings utilize solar energy by fossil fuels, solar thermal systems, and, most frequently nowadays, by photovoltaic systems based on optoelectric materials (1). The design of new synthetic materials coupled with a mechanism to capture, convert, and store photon energy will provide new ways to utilize solar energy (2, 3). However, achieving high conversion efficiency remains a challenge in such energy conversion systems.Recently, DNA has received attention in material sciences, especially for the fabrication of nanomachines able to perform nanoscale movements in response to external stimuli (4-11). Experimental and theoretical studies on single DNA nanomachines have led to the development of new energy conversion strategies (12, 13). As one of the most popular phototransformable molecules, azobenzene and its derivatives can change the overall structure by cis-trans isomerisation mechanism. Using the photoisomerization of azobenzene to photo-regulate DNA hybridization, (14) we have designed a single-molecule light-driven DNA nanomotor (15) for the continuous production of energy in the form of mechanical work. This photon-fueled nanomotor is simple and easy to operate, promising a unique approach to harvest photonic energy. Herein, azobenzene derivatives act as element for energy absorption and DNA molecules movement act for mechanical energy export. As we know, solar thermal technology is a technology to harvest solar thermal energy that converts solar energy to movement of molecules and then produces heat caused by molecule thermal moving. In our design, solar energy is converted to close-open movement of DNA molecules. However, few DNA motor molecules can undergo the close-open conversion as a result of the low p...

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Section: Resultsmentioning

confidence: 99%

Using silver nanowire antennas to enhance the conversion efficiency of photoresponsive DNA nanomotors

Yuan

Zhang²,

Chen³

et al. 2011

Proc. Natl. Acad. Sci. U.S.A.

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“…(C) In active plasmonics, resonant molecules can couple with the LSPR of nanostructures allowing for active control over resonance conditions that change the optical properties of the nanostructure. Reproduced with permission from [406] Copyright 2010 ACS. (D) Metal nanorods are organized to create a proposed superlens which can transfer color images of nanometer-sized objects to the far field for observation.…”

Section: Figurementioning

confidence: 99%

Controlling the Synthesis and Assembly of Silver Nanostructures for Plasmonic Applications

et al. 2011

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“…The dead bacteria seem not to attract sufficient amounts of AgNPs on their cell membrane to generate a signal, most part of bacterial surface is free of AgNPs. According to the SERS electromagnetic (EM) enhancement theory, the relation between the SERS intensity, I, and the local EM strength, E, is calculated to be I∝ |E| 4 , 28,29 and the relation between E and the distance between nanoparticles and analytes, D, is described as E∝(1/D) 12 . 30 Hence, a minute reduction of D leads to a significant enhancement of Table T1 in the Supporting Information).…”

Section: Introductionmentioning

confidence: 99%

Label-Free in Situ Discrimination of Live and Dead Bacteria by Surface-Enhanced Raman Scattering

et al. 2015

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Techniques to distinguish between live and dead bacteria in a quantitative manner are in high demand in numerous fields including medical care, food safety, and public security as well as basic science research. This work demonstrates new nanostructures (silver nanoparticles coating bacteria structure, Bacteria@AgNPs) and their utility for rapid counting of live and dead bacteria by surface-enhanced Raman scattering (SERS). We found that suspensions containing Gram-negative organisms as well as AgNPs give strong SERS signals of live bacteria when generated selectively on the particle surface. However, almost no SERS signals can be detected from Bacteria@AgNPs suspensions containing dead bacteria. We demonstrate successful quantification of different percentages of dead bacteria both in bulk liquid and on glass surfaces by using SERS mapping on a single cell basis. Furthermore, different chemicals have been used to elucidate the mechanism involved in this observation. Finally, we used the Bacteria@AgNPs method to detect antibiotic resistance of E. coli strains against several antibiotics used in human medicine.

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Turning on Resonant SERRS Using the Chromophore−Plasmon Coupling Created by Host−Guest Complexation at a Plasmonic Nanoarray

Cited by 45 publications

References 165 publications

Using silver nanowire antennas to enhance the conversion efficiency of photoresponsive DNA nanomotors

Using silver nanowire antennas to enhance the conversion efficiency of photoresponsive DNA nanomotors

Controlling the Synthesis and Assembly of Silver Nanostructures for Plasmonic Applications

Label-Free in Situ Discrimination of Live and Dead Bacteria by Surface-Enhanced Raman Scattering

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