Sensitive Hydrogen Sensors Based on Gold–Palladium Double Nanoblock

Author

Tae-Woo Lee ; Da Eun Lee ; Soon-Hong Kwon

Author_Institution

Dept. of Phys., Chung-Ang Univ., Seoul, South Korea

Volume

26

Issue

22

fYear

2014

fDate

Nov.15, 15 2014

Firstpage

2232

Lastpage

2235

Abstract

We suggest a new plasmonic hydrogen sensor based on a metal-air-metal cavity structure. The proposed cavity structure shows a high sensing performance with a large resonant wavelength shift of 84 nm due to strong plasmonic coupling at an air gap size of 8 nm. The cavity resonance has a narrow linewidth of 72 nm by suppressing radiational loss. Figure of merit, defined by the ratio between the wavelength shift and linewidth, is estimated to be 1.17, which means that the cavity can detect hydrogen gas effectively. In addition, optical losses in the plasmonic cavity, radiational loss, and metallic absorption losses are separately investigated as a function of air gap size.

Keywords

gas sensors; gold; hydrogen; nanosensors; nanostructured materials; optical losses; optical sensors; palladium; plasmonics; Au-Pd; H₂; air gap size; cavity resonance; figure of merit; gold-palladium double nanoblock; linewidth; metal-air-metal cavity structure; metallic absorption losses; optical losses; plasmonic cavity; plasmonic coupling; plasmonic hydrogen sensor; radiational loss; resonant wavelength shift; sensitive hydrogen gas sensors; Absorption; Cavity resonators; Gold; Hydrogen; Palladium; Plasmons; Sensors; Optical sensing and sensors; resonators; surface plasmons;

fLanguage

English

Journal_Title

Photonics Technology Letters, IEEE

Publisher

ieee

ISSN

1041-1135

Type

jour

DOI

10.1109/LPT.2014.2351403

Filename

6884785