Nonlinear terahertz metamaterials via field-enhanced carrier dynamics in GaAs

Kebin Fan; Harold Y. Hwang; Mengkun Liu; Andrew C. Strikwerda; Aaron Sternbach; Jingdi Zhang; Xiaoguang Zhao; Xin Zhang; Keith A. Nelson; Richard D. Averitt

doi:10.1103/PhysRevLett.110.217404

Nonlinear terahertz metamaterials via field-enhanced carrier dynamics in GaAs

Kebin Fan
, Harold Y. Hwang
, Mengkun Liu
, Andrew C. Strikwerda
, Aaron Sternbach
, Jingdi Zhang
, Xiaoguang Zhao
, Xin Zhang
, Keith A. Nelson
, Richard D. Averitt

Physics and Astronomy

Boston University
Massachusetts Institute of Technology

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

127 Scopus citations

Abstract

We demonstrate nonlinear metamaterial split ring resonators (SRRs) on GaAs at terahertz frequencies. For SRRs on doped GaAs films, incident terahertz radiation with peak fields of ∼20-160 kV/cm drives intervalley scattering. This reduces the carrier mobility and enhances the SRR LC response due to a conductivity decrease in the doped thin film. Above ∼160 kV/cm, electric field enhancement within the SRR gaps leads to efficient impact ionization, increasing the carrier density and the conductivity which, in turn, suppresses the SRR resonance. We demonstrate an increase of up to 10 orders of magnitude in the carrier density in the SRR gaps on semi-insulating GaAs. Furthermore, we show that the effective permittivity can be swept from negative to positive values with an increasing terahertz field strength in the impact ionization regime, enabling new possibilities for nonlinear metamaterials.

Original language	English
Article number	217404
Journal	Physical Review Letters
Volume	110
Issue number	21
DOIs	https://doi.org/10.1103/PhysRevLett.110.217404
State	Published - May 21 2013

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10.1103/PhysRevLett.110.217404

Cite this

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title = "Nonlinear terahertz metamaterials via field-enhanced carrier dynamics in GaAs",

abstract = "We demonstrate nonlinear metamaterial split ring resonators (SRRs) on GaAs at terahertz frequencies. For SRRs on doped GaAs films, incident terahertz radiation with peak fields of ∼20-160 kV/cm drives intervalley scattering. This reduces the carrier mobility and enhances the SRR LC response due to a conductivity decrease in the doped thin film. Above ∼160 kV/cm, electric field enhancement within the SRR gaps leads to efficient impact ionization, increasing the carrier density and the conductivity which, in turn, suppresses the SRR resonance. We demonstrate an increase of up to 10 orders of magnitude in the carrier density in the SRR gaps on semi-insulating GaAs. Furthermore, we show that the effective permittivity can be swept from negative to positive values with an increasing terahertz field strength in the impact ionization regime, enabling new possibilities for nonlinear metamaterials.",

author = "Kebin Fan and Hwang, \{Harold Y.\} and Mengkun Liu and Strikwerda, \{Andrew C.\} and Aaron Sternbach and Jingdi Zhang and Xiaoguang Zhao and Xin Zhang and Nelson, \{Keith A.\} and Averitt, \{Richard D.\}",

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T1 - Nonlinear terahertz metamaterials via field-enhanced carrier dynamics in GaAs

AU - Fan, Kebin

AU - Hwang, Harold Y.

AU - Liu, Mengkun

AU - Strikwerda, Andrew C.

AU - Sternbach, Aaron

AU - Zhang, Jingdi

AU - Zhao, Xiaoguang

AU - Zhang, Xin

AU - Nelson, Keith A.

AU - Averitt, Richard D.

PY - 2013/5/21

Y1 - 2013/5/21

N2 - We demonstrate nonlinear metamaterial split ring resonators (SRRs) on GaAs at terahertz frequencies. For SRRs on doped GaAs films, incident terahertz radiation with peak fields of ∼20-160 kV/cm drives intervalley scattering. This reduces the carrier mobility and enhances the SRR LC response due to a conductivity decrease in the doped thin film. Above ∼160 kV/cm, electric field enhancement within the SRR gaps leads to efficient impact ionization, increasing the carrier density and the conductivity which, in turn, suppresses the SRR resonance. We demonstrate an increase of up to 10 orders of magnitude in the carrier density in the SRR gaps on semi-insulating GaAs. Furthermore, we show that the effective permittivity can be swept from negative to positive values with an increasing terahertz field strength in the impact ionization regime, enabling new possibilities for nonlinear metamaterials.

AB - We demonstrate nonlinear metamaterial split ring resonators (SRRs) on GaAs at terahertz frequencies. For SRRs on doped GaAs films, incident terahertz radiation with peak fields of ∼20-160 kV/cm drives intervalley scattering. This reduces the carrier mobility and enhances the SRR LC response due to a conductivity decrease in the doped thin film. Above ∼160 kV/cm, electric field enhancement within the SRR gaps leads to efficient impact ionization, increasing the carrier density and the conductivity which, in turn, suppresses the SRR resonance. We demonstrate an increase of up to 10 orders of magnitude in the carrier density in the SRR gaps on semi-insulating GaAs. Furthermore, we show that the effective permittivity can be swept from negative to positive values with an increasing terahertz field strength in the impact ionization regime, enabling new possibilities for nonlinear metamaterials.

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DO - 10.1103/PhysRevLett.110.217404

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VL - 110

JO - Physical Review Letters

JF - Physical Review Letters

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ER -

Nonlinear terahertz metamaterials via field-enhanced carrier dynamics in GaAs

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