Nonlocal propagation and tunnelling of surface plasmons in metallic hourglass waveguides

Aeneas Wiener; Antonio I. Fernández-Domínguez; J. B. Pendry; Andrew P. Horsfield; Stefan A. Maier

doi:10.1364/OE.21.027509

Nonlocal propagation and tunnelling of surface plasmons in metallic hourglass waveguides

Aeneas Wiener, Antonio I. Fernández-Domínguez, J. B. Pendry, Andrew P. Horsfield, Stefan A. Maier

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

14 Citations (Scopus)

Abstract

The nanofocusing performance of hourglass plasmonic waveguides is studied analytically and numerically. Nonlocal effects in the linearly tapered metal-air-metal stack that makes up the device are taken into account within a hydrodynamical approach. Using this hourglass waveguide as a model structure, we show that spatial dispersion drastically modifies the propagation of surface plasmons in metal voids, such as those generated between touching particles. Specifically, we investigate how nonlocal corrections limit the enormous field enhancements predicted by local electromagnetic treatments of geometric singularities. Finally, our results also indicate the emergence of nonlocality assisted tunnelling of plasmonic modes across hourglass contacts as thick as 0.5 nm.

Original language	English
Pages (from-to)	27509-27518
Number of pages	10
Journal	Optics Express
Volume	21
Issue number	22
DOIs	https://doi.org/10.1364/OE.21.027509
Publication status	Published - 4 Nov 2013
Externally published	Yes

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10.1364/OE.21.027509Licence: CC BY

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abstract = "The nanofocusing performance of hourglass plasmonic waveguides is studied analytically and numerically. Nonlocal effects in the linearly tapered metal-air-metal stack that makes up the device are taken into account within a hydrodynamical approach. Using this hourglass waveguide as a model structure, we show that spatial dispersion drastically modifies the propagation of surface plasmons in metal voids, such as those generated between touching particles. Specifically, we investigate how nonlocal corrections limit the enormous field enhancements predicted by local electromagnetic treatments of geometric singularities. Finally, our results also indicate the emergence of nonlocality assisted tunnelling of plasmonic modes across hourglass contacts as thick as 0.5 nm.",

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AU - Wiener, Aeneas

AU - Fernández-Domínguez, Antonio I.

AU - Pendry, J. B.

AU - Horsfield, Andrew P.

AU - Maier, Stefan A.

PY - 2013/11/4

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N2 - The nanofocusing performance of hourglass plasmonic waveguides is studied analytically and numerically. Nonlocal effects in the linearly tapered metal-air-metal stack that makes up the device are taken into account within a hydrodynamical approach. Using this hourglass waveguide as a model structure, we show that spatial dispersion drastically modifies the propagation of surface plasmons in metal voids, such as those generated between touching particles. Specifically, we investigate how nonlocal corrections limit the enormous field enhancements predicted by local electromagnetic treatments of geometric singularities. Finally, our results also indicate the emergence of nonlocality assisted tunnelling of plasmonic modes across hourglass contacts as thick as 0.5 nm.

AB - The nanofocusing performance of hourglass plasmonic waveguides is studied analytically and numerically. Nonlocal effects in the linearly tapered metal-air-metal stack that makes up the device are taken into account within a hydrodynamical approach. Using this hourglass waveguide as a model structure, we show that spatial dispersion drastically modifies the propagation of surface plasmons in metal voids, such as those generated between touching particles. Specifically, we investigate how nonlocal corrections limit the enormous field enhancements predicted by local electromagnetic treatments of geometric singularities. Finally, our results also indicate the emergence of nonlocality assisted tunnelling of plasmonic modes across hourglass contacts as thick as 0.5 nm.

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Nonlocal propagation and tunnelling of surface plasmons in metallic hourglass waveguides

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