Electrical control of second harmonic generation in a graphene-based plasmonic Fano structure

Fajun Xiao; Weiren Zhu; Wuyun Shang; Ting Mei; Malin Premaratne; Jianlin Zhao

doi:10.1364/OE.23.003236

Electrical control of second harmonic generation in a graphene-based plasmonic Fano structure

Fajun Xiao, Weiren Zhu, Wuyun Shang, Ting Mei, Malin Premaratne, Jianlin Zhao

School of Physical Science and Technology

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

25 Scopus citations

Abstract

We propose a strategy for active control of second harmonic generation (SHG) in a plasmonic Fano structure by electrically doping its underlying monolayer graphene. A detailed theoretical model for the proposed scheme is developed and numerical simulations are carried out to demonstrate the operation. Specifically, we show that a merely 30 meV change in graphene Fermi level can result in 45 times increase in SHG peak intensity, accompanied by a resonance wavelength shift spanning 220 nm. Further analysis uncovers that such tunability in SHG arises from the Fermi-level-modulated graphene permittivity, the real and imaginary parts of which dominate the resonance wavelength and the intensity of SHG, respectively.

Original language	English
Pages (from-to)	3236-3244
Number of pages	9
Journal	Optics Express
Volume	23
Issue number	3
DOIs	https://doi.org/10.1364/OE.23.003236
State	Published - 9 Feb 2015

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title = "Electrical control of second harmonic generation in a graphene-based plasmonic Fano structure",

abstract = "We propose a strategy for active control of second harmonic generation (SHG) in a plasmonic Fano structure by electrically doping its underlying monolayer graphene. A detailed theoretical model for the proposed scheme is developed and numerical simulations are carried out to demonstrate the operation. Specifically, we show that a merely 30 meV change in graphene Fermi level can result in 45 times increase in SHG peak intensity, accompanied by a resonance wavelength shift spanning 220 nm. Further analysis uncovers that such tunability in SHG arises from the Fermi-level-modulated graphene permittivity, the real and imaginary parts of which dominate the resonance wavelength and the intensity of SHG, respectively.",

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AU - Xiao, Fajun

AU - Zhu, Weiren

AU - Shang, Wuyun

AU - Mei, Ting

AU - Premaratne, Malin

AU - Zhao, Jianlin

PY - 2015/2/9

Y1 - 2015/2/9

N2 - We propose a strategy for active control of second harmonic generation (SHG) in a plasmonic Fano structure by electrically doping its underlying monolayer graphene. A detailed theoretical model for the proposed scheme is developed and numerical simulations are carried out to demonstrate the operation. Specifically, we show that a merely 30 meV change in graphene Fermi level can result in 45 times increase in SHG peak intensity, accompanied by a resonance wavelength shift spanning 220 nm. Further analysis uncovers that such tunability in SHG arises from the Fermi-level-modulated graphene permittivity, the real and imaginary parts of which dominate the resonance wavelength and the intensity of SHG, respectively.

AB - We propose a strategy for active control of second harmonic generation (SHG) in a plasmonic Fano structure by electrically doping its underlying monolayer graphene. A detailed theoretical model for the proposed scheme is developed and numerical simulations are carried out to demonstrate the operation. Specifically, we show that a merely 30 meV change in graphene Fermi level can result in 45 times increase in SHG peak intensity, accompanied by a resonance wavelength shift spanning 220 nm. Further analysis uncovers that such tunability in SHG arises from the Fermi-level-modulated graphene permittivity, the real and imaginary parts of which dominate the resonance wavelength and the intensity of SHG, respectively.

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Electrical control of second harmonic generation in a graphene-based plasmonic Fano structure

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