Subwavelength Terahertz Resonance Imaging (STRING) for Molecular Fingerprinting

Taewoo Ha; Daehan Yoo; Chaejeong Heo; Ferran Vidal-Codina; Ngoc Cuong Nguyen; Kyung Ik Sim; Sang Hyun Park; Wujoon Cha; Sungsu Park; Jaime Peraire; Teun Teun Kim; Young Hee Lee; Sang Hyun Oh

doi:10.1021/acs.nanolett.2c04610

Subwavelength Terahertz Resonance Imaging (STRING) for Molecular Fingerprinting

Taewoo Ha, Daehan Yoo, Chaejeong Heo, Ferran Vidal-Codina, Ngoc Cuong Nguyen, Kyung Ik Sim, Sang Hyun Park, Wujoon Cha, Sungsu Park, Jaime Peraire, Teun Teun Kim, Young Hee Lee, Sang Hyun Oh

Electrical and Computer Engineering

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

4 Scopus citations

Abstract

Subwavelength terahertz (THz) imaging methods are highly desirable for biochemical sensing as well as materials sciences, yet sensitive spectral fingerprinting is still challenging in the frequency domain due to weak light-matter interactions. Here, we demonstrate subwavelength THz resonance imaging (STRING) that overcomes this limitation to achieve ultrasensitive molecular fingerprinting. STRING combines individual ring-shaped coaxial single resonators with near-field spectroscopy, yielding considerable sensitivity gains from both local field enhancement and the near-field effect. As an initial demonstration, we obtained spectral fingerprints from isomers of α-lactose and maltose monohydrates, achieving sensitivity that was enhanced by up to 10 orders of magnitude compared to far-field THz measurements with pelletized samples. Our results show that the STRING platform could enable the development of THz spectroscopy as a practical and sensitive tool for the fingerprinting and spectral imaging of molecules and nanoparticles.

Original language	English (US)
Pages (from-to)	10200-10207
Number of pages	8
Journal	Nano letters
Volume	22
Issue number	24
DOIs	https://doi.org/10.1021/acs.nanolett.2c04610
State	Published - Dec 28 2022

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Publisher Copyright:
© 2022 American Chemical Society.

Keywords

coaxial aperture
epsilon-near-zero (ENZ)
nanophotonics
near-field spectroscopy
spectral fingerprinting
terahertz imaging

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title = "Subwavelength Terahertz Resonance Imaging (STRING) for Molecular Fingerprinting",

abstract = "Subwavelength terahertz (THz) imaging methods are highly desirable for biochemical sensing as well as materials sciences, yet sensitive spectral fingerprinting is still challenging in the frequency domain due to weak light-matter interactions. Here, we demonstrate subwavelength THz resonance imaging (STRING) that overcomes this limitation to achieve ultrasensitive molecular fingerprinting. STRING combines individual ring-shaped coaxial single resonators with near-field spectroscopy, yielding considerable sensitivity gains from both local field enhancement and the near-field effect. As an initial demonstration, we obtained spectral fingerprints from isomers of α-lactose and maltose monohydrates, achieving sensitivity that was enhanced by up to 10 orders of magnitude compared to far-field THz measurements with pelletized samples. Our results show that the STRING platform could enable the development of THz spectroscopy as a practical and sensitive tool for the fingerprinting and spectral imaging of molecules and nanoparticles.",

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AU - Heo, Chaejeong

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AU - Nguyen, Ngoc Cuong

AU - Sim, Kyung Ik

AU - Park, Sang Hyun

AU - Cha, Wujoon

AU - Park, Sungsu

AU - Peraire, Jaime

AU - Kim, Teun Teun

AU - Lee, Young Hee

AU - Oh, Sang Hyun

PY - 2022/12/28

Y1 - 2022/12/28

N2 - Subwavelength terahertz (THz) imaging methods are highly desirable for biochemical sensing as well as materials sciences, yet sensitive spectral fingerprinting is still challenging in the frequency domain due to weak light-matter interactions. Here, we demonstrate subwavelength THz resonance imaging (STRING) that overcomes this limitation to achieve ultrasensitive molecular fingerprinting. STRING combines individual ring-shaped coaxial single resonators with near-field spectroscopy, yielding considerable sensitivity gains from both local field enhancement and the near-field effect. As an initial demonstration, we obtained spectral fingerprints from isomers of α-lactose and maltose monohydrates, achieving sensitivity that was enhanced by up to 10 orders of magnitude compared to far-field THz measurements with pelletized samples. Our results show that the STRING platform could enable the development of THz spectroscopy as a practical and sensitive tool for the fingerprinting and spectral imaging of molecules and nanoparticles.

AB - Subwavelength terahertz (THz) imaging methods are highly desirable for biochemical sensing as well as materials sciences, yet sensitive spectral fingerprinting is still challenging in the frequency domain due to weak light-matter interactions. Here, we demonstrate subwavelength THz resonance imaging (STRING) that overcomes this limitation to achieve ultrasensitive molecular fingerprinting. STRING combines individual ring-shaped coaxial single resonators with near-field spectroscopy, yielding considerable sensitivity gains from both local field enhancement and the near-field effect. As an initial demonstration, we obtained spectral fingerprints from isomers of α-lactose and maltose monohydrates, achieving sensitivity that was enhanced by up to 10 orders of magnitude compared to far-field THz measurements with pelletized samples. Our results show that the STRING platform could enable the development of THz spectroscopy as a practical and sensitive tool for the fingerprinting and spectral imaging of molecules and nanoparticles.

KW - coaxial aperture

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KW - near-field spectroscopy

KW - spectral fingerprinting

KW - terahertz imaging

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Subwavelength Terahertz Resonance Imaging (STRING) for Molecular Fingerprinting

Abstract

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Keywords

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