Enhanced nanoplasmonic heating in standoff sensing of explosive residues with infrared reflection-absorption spectroscopy

Nicholas Simin; Yangkyu Park; Dongkyu Lee; Thomas Thundat; Seonghwan Kim

doi:10.1364/OL.387653

Optics Letters
Vol. 45,
Issue 8,
pp. 2144-2147
(2020)
•https://doi.org/10.1364/OL.387653

Enhanced nanoplasmonic heating in standoff sensing of explosive residues with infrared reflection-absorption spectroscopy

Nicholas Simin, Yangkyu Park, Dongkyu Lee, Thomas Thundat, and Seonghwan Kim

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Nicholas Simin, Yangkyu Park, Dongkyu Lee, Thomas Thundat, and Seonghwan Kim, "Enhanced nanoplasmonic heating in standoff sensing of explosive residues with infrared reflection-absorption spectroscopy," Opt. Lett. 45, 2144-2147 (2020)

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Table of Contents Category
- Optical Sensors, Measurements, and Metrology
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About this Article
History
- Original Manuscript: January 20, 2020
- Revised Manuscript: February 26, 2020
- Manuscript Accepted: March 10, 2020
- Published: April 6, 2020

Abstract

Various standoff sensing techniques employing optical spectroscopy have been developed to address challenges in safely identifying trace amounts of explosives at a distance. A flexible anodic aluminum oxide (AAO) microcantilever and a high-power quantum cascade laser utilized as the infrared (IR) source are used for standoff IR reflection-absorption spectroscopy to detect explosive residues on a metal surface. Standoff sensing of trinitrotoluene (TNT) is demonstrated by exploiting the high thermomechanical sensitivity of a bimetallic AAO microcantilever. Moreover, sputtering gold onto the fabricated AAO nanowells generates a strong scattering and absorption of IR light in the wavelength range of 5.18 µm to 5.85 µm resulting in enhanced nanoplasmonic heating. Utilizing the IR absorption enhancement in this wavelength range, the plasmonic AAO cantilever could detect TNT molecules 7 times better than could the bimetallic AAO cantilever.

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Optics Letters