Influence of the evanescent field decay length on the sensitivity of plasmonic nanodisks and nanoholes

Francesco Mazzotta; Timothy W. Johnson; Andreas B. Dahlin; Jonah Shaver; Sang Hyun Oh; Fredrik Höök

doi:10.1021/ph500360d

Influence of the evanescent field decay length on the sensitivity of plasmonic nanodisks and nanoholes

Francesco Mazzotta, Timothy W. Johnson, Andreas B. Dahlin, Jonah Shaver, Sang Hyun Oh, Fredrik Höök

Electrical and Computer Engineering

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

87 Scopus citations

Abstract

We evaluate and compare the sensitivity of gold nanodisks on silica substrates and nanoholes made in silica-supported gold films, two of the most common sensor structures used in plasmonic biosensing. An alumina overcoat was applied by atomic layer deposition (ALD) to precisely control the interfacial refractive index and determine the evanescent plasmonic field decay length. The results are in good agreement with analytical models and biomolecular binding experiments for the two substrates. We found that nanodisks outperform nanoholes for thin dielectric coatings (<∼20 nm), while the opposite holds true for thicker coatings (>∼20 nm). The optimum nanoplasmonic transducer element for a given biorecognition reaction can be chosen based on experimentally determined bulk sensitivities/noise levels and theoretically estimated evanescent field decay lengths.

Original language	English (US)
Pages (from-to)	256-262
Number of pages	7
Journal	ACS Photonics
Volume	2
Issue number	2
DOIs	https://doi.org/10.1021/ph500360d
State	Published - Feb 18 2015

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Publisher Copyright:
© 2014 American Chemical Society.

Keywords

atomic layer deposition
biosensing
nanodisk
nanohole
plasmonics
surface plasmon resonance

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abstract = "We evaluate and compare the sensitivity of gold nanodisks on silica substrates and nanoholes made in silica-supported gold films, two of the most common sensor structures used in plasmonic biosensing. An alumina overcoat was applied by atomic layer deposition (ALD) to precisely control the interfacial refractive index and determine the evanescent plasmonic field decay length. The results are in good agreement with analytical models and biomolecular binding experiments for the two substrates. We found that nanodisks outperform nanoholes for thin dielectric coatings (<∼20 nm), while the opposite holds true for thicker coatings (>∼20 nm). The optimum nanoplasmonic transducer element for a given biorecognition reaction can be chosen based on experimentally determined bulk sensitivities/noise levels and theoretically estimated evanescent field decay lengths.",

keywords = "atomic layer deposition, biosensing, nanodisk, nanohole, plasmonics, surface plasmon resonance",

author = "Francesco Mazzotta and Johnson, {Timothy W.} and Dahlin, {Andreas B.} and Jonah Shaver and Oh, {Sang Hyun} and Fredrik H{\"o}{\"o}k",

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AU - Mazzotta, Francesco

AU - Johnson, Timothy W.

AU - Dahlin, Andreas B.

AU - Shaver, Jonah

AU - Oh, Sang Hyun

AU - Höök, Fredrik

PY - 2015/2/18

Y1 - 2015/2/18

N2 - We evaluate and compare the sensitivity of gold nanodisks on silica substrates and nanoholes made in silica-supported gold films, two of the most common sensor structures used in plasmonic biosensing. An alumina overcoat was applied by atomic layer deposition (ALD) to precisely control the interfacial refractive index and determine the evanescent plasmonic field decay length. The results are in good agreement with analytical models and biomolecular binding experiments for the two substrates. We found that nanodisks outperform nanoholes for thin dielectric coatings (<∼20 nm), while the opposite holds true for thicker coatings (>∼20 nm). The optimum nanoplasmonic transducer element for a given biorecognition reaction can be chosen based on experimentally determined bulk sensitivities/noise levels and theoretically estimated evanescent field decay lengths.

AB - We evaluate and compare the sensitivity of gold nanodisks on silica substrates and nanoholes made in silica-supported gold films, two of the most common sensor structures used in plasmonic biosensing. An alumina overcoat was applied by atomic layer deposition (ALD) to precisely control the interfacial refractive index and determine the evanescent plasmonic field decay length. The results are in good agreement with analytical models and biomolecular binding experiments for the two substrates. We found that nanodisks outperform nanoholes for thin dielectric coatings (<∼20 nm), while the opposite holds true for thicker coatings (>∼20 nm). The optimum nanoplasmonic transducer element for a given biorecognition reaction can be chosen based on experimentally determined bulk sensitivities/noise levels and theoretically estimated evanescent field decay lengths.

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KW - nanohole

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KW - surface plasmon resonance

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Influence of the evanescent field decay length on the sensitivity of plasmonic nanodisks and nanoholes

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