Gain-assisted propagation of electromagnetic energy in subwavelength surface plasmon polariton gap waveguides

Stefan A. Maier

doi:10.1016/j.optcom.2005.07.064

Gain-assisted propagation of electromagnetic energy in subwavelength surface plasmon polariton gap waveguides

Stefan A. Maier

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

146 Citations (Scopus)

Abstract

The propagation of electromagnetic energy via coupled surface plasmon polariton modes in a metal-insulator-metal heterostructure is analyzed analytically for a core material exhibiting optical gain. It is shown that a sufficiently large gain can completely compensate for the absorption losses due to energy dissipation in the metallic boundaries, enabling long-range transport with a confinement below the diffraction limit for on-chip switching and sensing applications. For a free-space wavelength of 1500 nm, lossless propagation in a gold-semiconductor-gold waveguide with a core size of 50 nm is predicted for a gain coefficient γ = 4830 cm^-1, comparable to that of semiconductor gain media. The gain requirements decrease with the use of low-index nanocrystal-doped glasses or polymers as core materials.

Original language	English
Pages (from-to)	295-299
Number of pages	5
Journal	Optics Communications
Volume	258
Issue number	2
DOIs	https://doi.org/10.1016/j.optcom.2005.07.064
Publication status	Published - 15 Feb 2006
Externally published	Yes

Keywords

Active media
Integrated optics
Metal gap waveguides
Surface plasmon polaritons

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10.1016/j.optcom.2005.07.064

Cite this

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title = "Gain-assisted propagation of electromagnetic energy in subwavelength surface plasmon polariton gap waveguides",

abstract = "The propagation of electromagnetic energy via coupled surface plasmon polariton modes in a metal-insulator-metal heterostructure is analyzed analytically for a core material exhibiting optical gain. It is shown that a sufficiently large gain can completely compensate for the absorption losses due to energy dissipation in the metallic boundaries, enabling long-range transport with a confinement below the diffraction limit for on-chip switching and sensing applications. For a free-space wavelength of 1500 nm, lossless propagation in a gold-semiconductor-gold waveguide with a core size of 50 nm is predicted for a gain coefficient γ = 4830 cm-1, comparable to that of semiconductor gain media. The gain requirements decrease with the use of low-index nanocrystal-doped glasses or polymers as core materials.",

keywords = "Active media, Integrated optics, Metal gap waveguides, Surface plasmon polaritons",

author = "Maier, \{Stefan A.\}",

note = "Funding Information: This work has been sponsored by the UK Engineering and Physical Sciences Research Council (EPSRC). ",

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AU - Maier, Stefan A.

N1 - Funding Information: This work has been sponsored by the UK Engineering and Physical Sciences Research Council (EPSRC).

PY - 2006/2/15

Y1 - 2006/2/15

N2 - The propagation of electromagnetic energy via coupled surface plasmon polariton modes in a metal-insulator-metal heterostructure is analyzed analytically for a core material exhibiting optical gain. It is shown that a sufficiently large gain can completely compensate for the absorption losses due to energy dissipation in the metallic boundaries, enabling long-range transport with a confinement below the diffraction limit for on-chip switching and sensing applications. For a free-space wavelength of 1500 nm, lossless propagation in a gold-semiconductor-gold waveguide with a core size of 50 nm is predicted for a gain coefficient γ = 4830 cm-1, comparable to that of semiconductor gain media. The gain requirements decrease with the use of low-index nanocrystal-doped glasses or polymers as core materials.

AB - The propagation of electromagnetic energy via coupled surface plasmon polariton modes in a metal-insulator-metal heterostructure is analyzed analytically for a core material exhibiting optical gain. It is shown that a sufficiently large gain can completely compensate for the absorption losses due to energy dissipation in the metallic boundaries, enabling long-range transport with a confinement below the diffraction limit for on-chip switching and sensing applications. For a free-space wavelength of 1500 nm, lossless propagation in a gold-semiconductor-gold waveguide with a core size of 50 nm is predicted for a gain coefficient γ = 4830 cm-1, comparable to that of semiconductor gain media. The gain requirements decrease with the use of low-index nanocrystal-doped glasses or polymers as core materials.

KW - Active media

KW - Integrated optics

KW - Metal gap waveguides

KW - Surface plasmon polaritons

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DO - 10.1016/j.optcom.2005.07.064

M3 - Article

AN - SCOPUS:29344453528

SN - 0030-4018

VL - 258

SP - 295

EP - 299

JO - Optics Communications

JF - Optics Communications

IS - 2

ER -

Gain-assisted propagation of electromagnetic energy in subwavelength surface plasmon polariton gap waveguides

Abstract

Keywords

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