Fano Resonance in an Electrically Driven Plasmonic Device

Yuval Vardi; Eyal Cohen-Hoshen; Guy Shalem; Israel Bar-Joseph

doi:10.1021/acs.nanolett.5b04622

Fano Resonance in an Electrically Driven Plasmonic Device

Yuval Vardi, Eyal Cohen-Hoshen, Guy Shalem, Israel Bar-Joseph

Department of Condensed Matter Physics

Weizmann Institute of Science

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

Abstract

We present an electrically driven plasmonic device consisting of a gold nanoparticle trapped in a gap between two electrodes. The tunneling current in the device generates plasmons, which decay radiatively. The emitted spectrum extends up to an energy that depends on the applied voltage. Characterization of the electrical conductance at low temperatures allows us to extract the voltage drop on each tunnel barrier and the corresponding emitted spectrum. In several devices we find a pronounced sharp asymmetrical dip in the spectrum, which we identify as a Fano resonance. Finite-difference time-domain calculations reveal that this resonance is due to interference between the nanoparticle and electrodes dipolar fields and can be conveniently controlled by the structural parameters.

Original language	English
Pages (from-to)	748-752
Number of pages	5
Journal	Nano Letters
Volume	16
Issue number	1
Early online date	4 Jan 2016
DOIs	https://doi.org/10.1021/acs.nanolett.5b04622
State	Published - 13 Jan 2016

All Science Journal Classification (ASJC) codes

General Chemistry
Condensed Matter Physics
Mechanical Engineering
Bioengineering
General Materials Science

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10.1021/acs.nanolett.5b04622

http://arxiv.org/abs/1601.00315License: Other

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title = "Fano Resonance in an Electrically Driven Plasmonic Device",

abstract = "We present an electrically driven plasmonic device consisting of a gold nanoparticle trapped in a gap between two electrodes. The tunneling current in the device generates plasmons, which decay radiatively. The emitted spectrum extends up to an energy that depends on the applied voltage. Characterization of the electrical conductance at low temperatures allows us to extract the voltage drop on each tunnel barrier and the corresponding emitted spectrum. In several devices we find a pronounced sharp asymmetrical dip in the spectrum, which we identify as a Fano resonance. Finite-difference time-domain calculations reveal that this resonance is due to interference between the nanoparticle and electrodes dipolar fields and can be conveniently controlled by the structural parameters.",

author = "Yuval Vardi and Eyal Cohen-Hoshen and Guy Shalem and Israel Bar-Joseph",

note = "We would like to thank D. Mahalu and O. Raslin for their help in the electron beam lithography. Y.V. and E. C.-H. contributed equally to this work.",

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AU - Bar-Joseph, Israel

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N2 - We present an electrically driven plasmonic device consisting of a gold nanoparticle trapped in a gap between two electrodes. The tunneling current in the device generates plasmons, which decay radiatively. The emitted spectrum extends up to an energy that depends on the applied voltage. Characterization of the electrical conductance at low temperatures allows us to extract the voltage drop on each tunnel barrier and the corresponding emitted spectrum. In several devices we find a pronounced sharp asymmetrical dip in the spectrum, which we identify as a Fano resonance. Finite-difference time-domain calculations reveal that this resonance is due to interference between the nanoparticle and electrodes dipolar fields and can be conveniently controlled by the structural parameters.

AB - We present an electrically driven plasmonic device consisting of a gold nanoparticle trapped in a gap between two electrodes. The tunneling current in the device generates plasmons, which decay radiatively. The emitted spectrum extends up to an energy that depends on the applied voltage. Characterization of the electrical conductance at low temperatures allows us to extract the voltage drop on each tunnel barrier and the corresponding emitted spectrum. In several devices we find a pronounced sharp asymmetrical dip in the spectrum, which we identify as a Fano resonance. Finite-difference time-domain calculations reveal that this resonance is due to interference between the nanoparticle and electrodes dipolar fields and can be conveniently controlled by the structural parameters.

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Fano Resonance in an Electrically Driven Plasmonic Device

Abstract

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