Surface plasmon induced transparency in coupled microcavities assisted by slits

Zhang, Yubin; Chen, Junxue

doi:10.7498/aps.69.20200369

Cited by 2 publications

(1 citation statement)

References 20 publications

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“…但是, 热效应的调谐速度为微秒甚至毫秒级, 无法满足未来光通信对于超快调制的要求. Lu等 [27] 基于一种Ag-BaO的光学Kerr非线性材料, 设计了一种超快调制的全光开关器件. 但是, Ag-BaO的三阶非线性极化率太小, 导致所需泵浦光强高达650 MW/cm 2 .…”

Section: Mim)的等离子体波导结构具有强的光场限制能unclassified

Three-band plasmon induced transparency effect based on four-disk resonator coupled waveguide system

Zhu¹,

Gao²,

Zeng³

et al. 2022

Acta Phys. Sin.

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In order to reduce power, realize ultrafast response time and dynamic tunability, a plasmonic waveguide system based on four disk resonators is designed. A plasmon induced transparency effect is theoretically analyzed using two different methods:one is the direct destructive interference between bright and dark mode resonators, and the other is the indirect coupling through a plasmonic waveguide. Due to the giant effective nonlinear Kerr coefficient of the graphene-Ag composite material structure and the enhancement characteristics of slow light response to optical Kerr effect, the pump intensity of PIT system to change the phase shift of transmission spectrum is greatly reduced. An ultrafast response time of 1 ps is achieved. 0.4π, 0.8π, 1.2π, 1.6π and 2π-phase shift of the transmission spectrum in the plasmon induced transparency system are achieved with the intensity of the pump light as low as 2.34, 4.68, 7.02, 9.36 and 11.7 MW/cm<sup>-2</sup>. In this paper, two small disk resonators directly coupled with a plasmonic waveguide is employed, and the reason is that two small disk resonators play the role of the slit between the waveguide and the resonators, and also acts as two separate resonators side-coupled with a plasmonic waveguide, which leads to the more efficient coupling of electromagnetic energy in the waveguide into the big disk resonators to form resonance and easier storage of light in the resonator. The triple-band plasmon induced transparency (PIT) effect and slow light properties of the model are analyzed by the expression of the deduced theoretical transmittance based on the coupled mode theory, which are very consistent with the finite-difference time-domain simulations. The results show that the transmission peak of the system is over 80% and the maximum group index is as high as 368. What's more, the disk resonators are easy to fabricate and the size of the entire PIT structure is <0.5 μm<sup>2</sup>, which is benefit for design of optoelectronic devices on-chip integration. The research results have important application prospects in highly integrated optical circuits and networks, and also provide ideas for the design and fabrication of multi-channel optical filter and light storage devices with low power consumption, ultrafast nonlinear responses ultracompact and dynamically tunability.

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Section: Mim)的等离子体波导结构具有强的光场限制能unclassified

Three-band plasmon induced transparency effect based on four-disk resonator coupled waveguide system

Zhu¹,

Gao²,

Zeng³

et al. 2022

Acta Phys. Sin.

View full text Add to dashboard Cite

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Theoretical analysis of tunable double plasmon induced transparency in three-ellipse-shaped resonator coupled waveguide

Gu¹,

Zhang²,

Li³

et al. 2022

Acta Phys. Sin.

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The tunable double plasmon-induced transparency (PIT) effects are investigated in the three ellipse-shaped resonators coupled waveguide. By the finite element method, we study the influence of the three ellipse-shaped resonators coupling modes, waveguide structure parameters and the refractive indices of dielectric in three ellipse-shaped resonators on double PIT effects. The waveguide structure consists of three ellipse-shaped resonators, which is analogous to the four-level structure of the atomic system. The bottom ellipse-shaped resonator can be named as a bright mode, the middle and top ellipse-shaped resonators can be seen as dark mode. In order to obtain the ideal double PIT transparency windows, we also numerically analyze the optical transmission characteristics of several three ellipse-shaped resonators coupled waveguide structures. Furthermore, we mainly discuss the transmission spectra in the better three ellipse-shaped resonators coupled waveguide structure as a function of the radii of the long axis in ellipse-shaped resonators, the coupling distance between the bottom ellipse-shaped resonator and the bus waveguide, the coupling distance between ellipse-shaped resonators, and the symmetry broken degree. In addition, we also consider the effect of the refractive indices of dielectric in three ellipse-shaped resonators on double PIT spectra. It is found that the transmission spectra in the three ellipse-shaped resonators coupled waveguide have obvious red shift when the refractive indices of dielectric in three ellipse-shaped resonators increase. All the simulation results may provide the theoretical basis for the potential application of multiple PIT in plasma switches and sensors.

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Surface plasmon induced transparency in coupled microcavities assisted by slits

Cited by 2 publications

References 20 publications

Three-band plasmon induced transparency effect based on four-disk resonator coupled waveguide system

Three-band plasmon induced transparency effect based on four-disk resonator coupled waveguide system

Theoretical analysis of tunable double plasmon induced transparency in three-ellipse-shaped resonator coupled waveguide

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