Efficient plasmonic gas sensing based on cavity-coupled metallic nanoparticles

Jian Qin; Yu Hui Chen; Boyang Ding; Richard J. Blaikie; Min Qiu

doi:10.1021/acs.jpcc.7b06502

Efficient plasmonic gas sensing based on cavity-coupled metallic nanoparticles

Jian Qin, Yu Hui Chen, Boyang Ding^*, Richard J. Blaikie, Min Qiu

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

21 Citations (Scopus)

Abstract

Here, we demonstrate the gas sensing ability of cavitycoupled metallic nanoparticle systems, comprising gold nanoparticles separated from a gold mirror with a polymer spacer. An increase in relative humidity (RH) causes the spacer to expand, which induces a significant reduction of nanoparticle scattering intensity, as the scattering is highly dependent on the cavity-nanoparticle coupling that closely relates to the nanoparticle-mirror distance. With high structural tolerance, i.e., no requirement for high-precision nanoparticle geometry, this lithography-free system enables a remarkable average sensitivity at 0.12 dB/% RH and 0.25 dB/% RH over a wide RH range (45-75%) and full reversibility with much faster response time than the commercial electrochemical sensors, possessing the characteristics to be used for notable gas sensing.

Original language	English
Journal	Journal of Physical Chemistry C
Volume	121
Issue number	39
DOIs	https://doi.org/10.1021/acs.jpcc.7b06502
Publication status	Published - 2017
Externally published	Yes

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title = "Efficient plasmonic gas sensing based on cavity-coupled metallic nanoparticles",

abstract = "Here, we demonstrate the gas sensing ability of cavitycoupled metallic nanoparticle systems, comprising gold nanoparticles separated from a gold mirror with a polymer spacer. An increase in relative humidity (RH) causes the spacer to expand, which induces a significant reduction of nanoparticle scattering intensity, as the scattering is highly dependent on the cavity-nanoparticle coupling that closely relates to the nanoparticle-mirror distance. With high structural tolerance, i.e., no requirement for high-precision nanoparticle geometry, this lithography-free system enables a remarkable average sensitivity at 0.12 dB/% RH and 0.25 dB/% RH over a wide RH range (45-75%) and full reversibility with much faster response time than the commercial electrochemical sensors, possessing the characteristics to be used for notable gas sensing.",

author = "Jian Qin and Chen, {Yu Hui} and Boyang Ding and Blaikie, {Richard J.} and Min Qiu",

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AU - Qin, Jian

AU - Chen, Yu Hui

AU - Ding, Boyang

AU - Blaikie, Richard J.

AU - Qiu, Min

PY - 2017

Y1 - 2017

N2 - Here, we demonstrate the gas sensing ability of cavitycoupled metallic nanoparticle systems, comprising gold nanoparticles separated from a gold mirror with a polymer spacer. An increase in relative humidity (RH) causes the spacer to expand, which induces a significant reduction of nanoparticle scattering intensity, as the scattering is highly dependent on the cavity-nanoparticle coupling that closely relates to the nanoparticle-mirror distance. With high structural tolerance, i.e., no requirement for high-precision nanoparticle geometry, this lithography-free system enables a remarkable average sensitivity at 0.12 dB/% RH and 0.25 dB/% RH over a wide RH range (45-75%) and full reversibility with much faster response time than the commercial electrochemical sensors, possessing the characteristics to be used for notable gas sensing.

AB - Here, we demonstrate the gas sensing ability of cavitycoupled metallic nanoparticle systems, comprising gold nanoparticles separated from a gold mirror with a polymer spacer. An increase in relative humidity (RH) causes the spacer to expand, which induces a significant reduction of nanoparticle scattering intensity, as the scattering is highly dependent on the cavity-nanoparticle coupling that closely relates to the nanoparticle-mirror distance. With high structural tolerance, i.e., no requirement for high-precision nanoparticle geometry, this lithography-free system enables a remarkable average sensitivity at 0.12 dB/% RH and 0.25 dB/% RH over a wide RH range (45-75%) and full reversibility with much faster response time than the commercial electrochemical sensors, possessing the characteristics to be used for notable gas sensing.

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VL - 121

JO - Journal of Physical Chemistry C

JF - Journal of Physical Chemistry C

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Efficient plasmonic gas sensing based on cavity-coupled metallic nanoparticles

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