Infrared Plasmonics via ZnO
Document Type
Article
Publication Date
7-6-2014
Identifier/URL
40783062 (Pure)
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Abstract
Conventional plasmonic devices involve metals, but metal-based plasmonic resonances are mainly limited to λres < 1 μm, and thus metals interact effectively only with light in the UV and visible ranges. We show that highly doped ZnO can exhibit λres ≥ 1 μm, thus moving plasmonics into the IR range. We illustrate this capability with a set of thin (d = 25–147 nm) Al-doped ZnO (AZO) layers grown by RF sputtering on quartz glass. These samples employ a unique, 20-nm-thick, ZnON buffer layer, which minimizes the strong thickness dependence of mobility (μ) on thickness (d). A practical waveguide structure, using these measurements, is simulated with COMSOL Multiphysics software over a mid-IR wavelength range of 4–10 μm, with a detailed examination of propagation loss and plasmon confinement dimension. In many cases, Lplas < λlight, thus showing that IR light can be manipulated in semiconductor materials at dimensions below the diffraction limit.
Repository Citation
Teherani, F. H.,
Look, D. C.,
& Rogers, D. J.
(2014). Infrared Plasmonics via ZnO. Journal of Nano Research, 28, 109-119.
https://corescholar.libraries.wright.edu/physics/1511
DOI
10.4028/www.scientific.net/JNanoR.28.109
