Electromagnetic interaction between a metallic nanoparticle and surface in tunnelling proximity-modelling and experiment

J. Mitra; Lei Feng; Michael G. Boyle; P. Dawson

doi:10.1088/0022-3727/42/21/215101

Electromagnetic interaction between a metallic nanoparticle and surface in tunnelling proximity-modelling and experiment

J. Mitra, Lei Feng, Michael G. Boyle, P. Dawson

School of Mathematics and Physics

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15 Citations (Scopus)

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Abstract

We simulate the localized surface plasmon resonances of an Au nanoparticle within tunnelling proximity of an Au substrate. The results demonstrate that the calculated resonance energies can be identified with those experimentally detected for light emission from the tip–sample junction of a scanning tunnelling microscope. Relative to the modes of an isolated nanoparticle these modes show significant red-shifting, extending further into the infrared with increasing radius, primarily due to a proximity-induced lowering of the effective bulk plasmon frequency. Spatial mapping of the field enhancement factor shows an oscillatory variation of the field, absent in the case of a dielectric substrate; also the degree of localization of the modes, and thus the resolution achievable electromagnetically, is shown to depend primarily on the nanoparticle radius, which is only weakly dependent on wavelength.

Original language	English
Article number	215101
Number of pages	7
Journal	Journal of Physics D: Applied Physics
Volume	42
Issue number	21
Early online date	13 Oct 2009
DOIs	https://doi.org/10.1088/0022-3727/42/21/215101
Publication status	Published - 07 Nov 2009

ASJC Scopus subject areas

Electronic, Optical and Magnetic Materials
Surfaces, Coatings and Films
Acoustics and Ultrasonics
Condensed Matter Physics

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title = "Electromagnetic interaction between a metallic nanoparticle and surface in tunnelling proximity-modelling and experiment",

abstract = "We simulate the localized surface plasmon resonances of an Au nanoparticle within tunnelling proximity of an Au substrate. The results demonstrate that the calculated resonance energies can be identified with those experimentally detected for light emission from the tip–sample junction of a scanning tunnelling microscope. Relative to the modes of an isolated nanoparticle these modes show significant red-shifting, extending further into the infrared with increasing radius, primarily due to a proximity-induced lowering of the effective bulk plasmon frequency. Spatial mapping of the field enhancement factor shows an oscillatory variation of the field, absent in the case of a dielectric substrate; also the degree of localization of the modes, and thus the resolution achievable electromagnetically, is shown to depend primarily on the nanoparticle radius, which is only weakly dependent on wavelength.",

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AU - Mitra, J.

AU - Feng, Lei

AU - Boyle, Michael G.

AU - Dawson, P.

PY - 2009/11/7

Y1 - 2009/11/7

N2 - We simulate the localized surface plasmon resonances of an Au nanoparticle within tunnelling proximity of an Au substrate. The results demonstrate that the calculated resonance energies can be identified with those experimentally detected for light emission from the tip–sample junction of a scanning tunnelling microscope. Relative to the modes of an isolated nanoparticle these modes show significant red-shifting, extending further into the infrared with increasing radius, primarily due to a proximity-induced lowering of the effective bulk plasmon frequency. Spatial mapping of the field enhancement factor shows an oscillatory variation of the field, absent in the case of a dielectric substrate; also the degree of localization of the modes, and thus the resolution achievable electromagnetically, is shown to depend primarily on the nanoparticle radius, which is only weakly dependent on wavelength.

AB - We simulate the localized surface plasmon resonances of an Au nanoparticle within tunnelling proximity of an Au substrate. The results demonstrate that the calculated resonance energies can be identified with those experimentally detected for light emission from the tip–sample junction of a scanning tunnelling microscope. Relative to the modes of an isolated nanoparticle these modes show significant red-shifting, extending further into the infrared with increasing radius, primarily due to a proximity-induced lowering of the effective bulk plasmon frequency. Spatial mapping of the field enhancement factor shows an oscillatory variation of the field, absent in the case of a dielectric substrate; also the degree of localization of the modes, and thus the resolution achievable electromagnetically, is shown to depend primarily on the nanoparticle radius, which is only weakly dependent on wavelength.

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DO - 10.1088/0022-3727/42/21/215101

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JO - Journal of Physics D: Applied Physics

JF - Journal of Physics D: Applied Physics

IS - 21

M1 - 215101

ER -

Electromagnetic interaction between a metallic nanoparticle and surface in tunnelling proximity-modelling and experiment

Abstract

ASJC Scopus subject areas

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