Ultrasensitive broadband probing of molecular vibrational modes with multifrequency optical antennas

Heykel Aouani; Hana Šípová; Mohsen Rahmani; Miguel Navarro-Cia; Kateřina Hegnerová; Jiří Homola; Minghui Hong; Stefan A. Maier

doi:10.1021/nn304860t

Ultrasensitive broadband probing of molecular vibrational modes with multifrequency optical antennas

Heykel Aouani^*, Hana Šípová, Mohsen Rahmani, Miguel Navarro-Cia, Kateřina Hegnerová, Jiří Homola, Minghui Hong, Stefan A. Maier

^*Corresponding author for this work

Engineering and Physical Sciences

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

101 Citations (Scopus)

Abstract

Optical antennas represent an enabling technology for enhancing the detection of molecular vibrational signatures at low concentrations and probing the chemical composition of a sample in order to identify target molecules. However, efficiently detecting different vibrational modes to determine the presence (or the absence) of a molecular species requires a multispectral interrogation in a window of several micrometers, as many molecules present informative fingerprint spectra in the mid-infrared between 2.5 and 10 μm. As most nanoantennas exhibit a narrow-band response because of their dipolar nature, they are not suitable for such applications. Here, we propose the use of multifrequency optical antennas designed for operating with a bandwidth of several octaves. We demonstrate that surface-enhanced infrared absorption gains in the order of 10⁵ can be easily obtained in a spectral window of 3 μm with attomolar concentrations of molecules, providing new opportunities for ultrasensitive broadband detection of molecular species via vibrational spectroscopy techniques.

Original language	English
Pages (from-to)	669-675
Number of pages	7
Journal	ACS Nano
Volume	7
Issue number	1
DOIs	https://doi.org/10.1021/nn304860t
Publication status	Published - 22 Jan 2013

Keywords

broadband optical antenna
field enhancement
nanoantenna
plasmonic
SEIRA
vibrational spectroscopy

ASJC Scopus subject areas

General Engineering
General Materials Science
General Physics and Astronomy

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10.1021/nn304860t

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title = "Ultrasensitive broadband probing of molecular vibrational modes with multifrequency optical antennas",

abstract = "Optical antennas represent an enabling technology for enhancing the detection of molecular vibrational signatures at low concentrations and probing the chemical composition of a sample in order to identify target molecules. However, efficiently detecting different vibrational modes to determine the presence (or the absence) of a molecular species requires a multispectral interrogation in a window of several micrometers, as many molecules present informative fingerprint spectra in the mid-infrared between 2.5 and 10 μm. As most nanoantennas exhibit a narrow-band response because of their dipolar nature, they are not suitable for such applications. Here, we propose the use of multifrequency optical antennas designed for operating with a bandwidth of several octaves. We demonstrate that surface-enhanced infrared absorption gains in the order of 105 can be easily obtained in a spectral window of 3 μm with attomolar concentrations of molecules, providing new opportunities for ultrasensitive broadband detection of molecular species via vibrational spectroscopy techniques.",

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AU - Aouani, Heykel

AU - Šípová, Hana

AU - Rahmani, Mohsen

AU - Navarro-Cia, Miguel

AU - Hegnerová, Kateřina

AU - Homola, Jiří

AU - Hong, Minghui

AU - Maier, Stefan A.

PY - 2013/1/22

Y1 - 2013/1/22

N2 - Optical antennas represent an enabling technology for enhancing the detection of molecular vibrational signatures at low concentrations and probing the chemical composition of a sample in order to identify target molecules. However, efficiently detecting different vibrational modes to determine the presence (or the absence) of a molecular species requires a multispectral interrogation in a window of several micrometers, as many molecules present informative fingerprint spectra in the mid-infrared between 2.5 and 10 μm. As most nanoantennas exhibit a narrow-band response because of their dipolar nature, they are not suitable for such applications. Here, we propose the use of multifrequency optical antennas designed for operating with a bandwidth of several octaves. We demonstrate that surface-enhanced infrared absorption gains in the order of 105 can be easily obtained in a spectral window of 3 μm with attomolar concentrations of molecules, providing new opportunities for ultrasensitive broadband detection of molecular species via vibrational spectroscopy techniques.

AB - Optical antennas represent an enabling technology for enhancing the detection of molecular vibrational signatures at low concentrations and probing the chemical composition of a sample in order to identify target molecules. However, efficiently detecting different vibrational modes to determine the presence (or the absence) of a molecular species requires a multispectral interrogation in a window of several micrometers, as many molecules present informative fingerprint spectra in the mid-infrared between 2.5 and 10 μm. As most nanoantennas exhibit a narrow-band response because of their dipolar nature, they are not suitable for such applications. Here, we propose the use of multifrequency optical antennas designed for operating with a bandwidth of several octaves. We demonstrate that surface-enhanced infrared absorption gains in the order of 105 can be easily obtained in a spectral window of 3 μm with attomolar concentrations of molecules, providing new opportunities for ultrasensitive broadband detection of molecular species via vibrational spectroscopy techniques.

KW - broadband optical antenna

KW - field enhancement

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Ultrasensitive broadband probing of molecular vibrational modes with multifrequency optical antennas

Abstract

Keywords

ASJC Scopus subject areas

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