The Remote Light Emission Modulated by Local Surface Plasmon Resonance for the CdSe NW–Au NP Hybrid Structure

The Remote Light Emission Modulated by Local Surface Plasmon Resonance for the CdSe NW–Au NP Hybrid Structure

CdSe nanowire (NW)–Au nanoparticle (NP) compounds are synthesized successfully using the method of physical vapor deposition, and the modulated remote emission is realized in the hybrid structure with strong metal–semiconductor coupling. The well‐crystallized, uniform morphology, smooth surface CdSe...

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Veröffentlicht in:Advanced materials interfaces 2019-01, Vol.6 (2), p.n/a
Hauptverfasser: He, Jingru, Li, Jing, Xia, Jing, Tian, Lifeng, Jin, Binbin, Zhou, Shaomin, Sun, Mengtao, Meng, Xiangmin
Format: Artikel
Sprache:eng
Schlagworte:
Au NP
Cadmium selenides
CdSe NW
Coupling
Crystallization
Electric fields
Excitons
Gold
Hybrid structures
Hybrid systems
Light emission
localized electromagnetic field enhancement
Morphology
Nanoparticles
Nanowires
Photoluminescence
Physical vapor deposition
remote light emission
Remote sensing
Surface plasmon resonance
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container_issue 2
container_start_page
container_title Advanced materials interfaces
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creator He, Jingru
Li, Jing
Xia, Jing
Tian, Lifeng
Jin, Binbin
Zhou, Shaomin
Sun, Mengtao
Meng, Xiangmin
description CdSe nanowire (NW)–Au nanoparticle (NP) compounds are synthesized successfully using the method of physical vapor deposition, and the modulated remote emission is realized in the hybrid structure with strong metal–semiconductor coupling. The well‐crystallized, uniform morphology, smooth surface CdSe NW is attached with an Au NP on the terminal, which forms the integration structure with direct plasmon–exciton coupling of semiconductor–metal hybrid system. When the CdSe terminal or Au NP terminal of the hybrid structure is excited by the laser with wavelength of 633 nm, the remote light emission at another terminal is greatly modulated. To reveal the physical mechanism of energy conviction between plasmon and exciton, finite‐difference time‐domain simulations are performed for the CdSe NW–Au NP hybrid structures. The calculated results confirm that the modulation of remote light emission is attributed to the competing of the quench of photoluminescence and the electric field enhancement of local surface plasmon resonance. These works can provide deeper understanding of physical mechanism of plasmon and exciton coupling, and open up new application for the remote light sensing and detection. The CdSe NW attached with an Au NP on the terminal forms the semiconductor–metal hybrid structure. When one terminal is excited by the laser, the remote light emission at another terminal is modulated. The FDTD simulations results confirm that the modulation is attributed to the competition of the quench of photoluminescence and the electric field enhancement of local SPR.
doi_str_mv 10.1002/admi.201801418
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The well‐crystallized, uniform morphology, smooth surface CdSe NW is attached with an Au NP on the terminal, which forms the integration structure with direct plasmon–exciton coupling of semiconductor–metal hybrid system. When the CdSe terminal or Au NP terminal of the hybrid structure is excited by the laser with wavelength of 633 nm, the remote light emission at another terminal is greatly modulated. To reveal the physical mechanism of energy conviction between plasmon and exciton, finite‐difference time‐domain simulations are performed for the CdSe NW–Au NP hybrid structures. The calculated results confirm that the modulation of remote light emission is attributed to the competing of the quench of photoluminescence and the electric field enhancement of local surface plasmon resonance. These works can provide deeper understanding of physical mechanism of plasmon and exciton coupling, and open up new application for the remote light sensing and detection. The CdSe NW attached with an Au NP on the terminal forms the semiconductor–metal hybrid structure. When one terminal is excited by the laser, the remote light emission at another terminal is modulated. 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The CdSe NW attached with an Au NP on the terminal forms the semiconductor–metal hybrid structure. When one terminal is excited by the laser, the remote light emission at another terminal is modulated. 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source Wiley Online Library Journals Frontfile Complete
subjects Au NP
Cadmium selenides
CdSe NW
Coupling
Crystallization
Electric fields
Excitons
Gold
Hybrid structures
Hybrid systems
Light emission
localized electromagnetic field enhancement
Morphology
Nanoparticles
Nanowires
Photoluminescence
Physical vapor deposition
remote light emission
Remote sensing
Surface plasmon resonance
title The Remote Light Emission Modulated by Local Surface Plasmon Resonance for the CdSe NW–Au NP Hybrid Structure
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