Dispersion relation for surface plasmon polaritons in metal/nonlinear-dielectric/metal slot waveguides

Rukhlenko, Ivan D.; Pannipitiya, Asanka; Premaratne, Malin

doi:10.1364/ol.36.003374

Cited by 45 publications

(36 citation statements)

References 9 publications

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“…11 reduces to the dispersion relation of the SPs supported by a simple nonlinear slot waveguide. In addition, as it has been proven for a plasmonic waveguide [24,25], we recover the dispersion relation of a symmetric graphene-covered PPW with a linear core medium when α → 0.…”

Section: Dispersion Relation For Guided Plasmonsmentioning

confidence: 62%

“…9 of ref. [24] and, thus, Eq. 11 reduces to the dispersion relation of the SPs supported by a simple nonlinear slot waveguide.…”

Section: Dispersion Relation For Guided Plasmonsmentioning

confidence: 95%

“…[24,25], we derive an exact dispersion relation for the TM SPs of a symmetric slot waveguide formed by a nonlinear Kerr slab of width d and permittivity ε 1 = ε l 1 + α|E| 2 , which is sandwiched between two graphene monolayers at x = ±d/2 (see Fig. 1).…”

Section: Introductionmentioning

confidence: 99%

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Guided Plasmon Modes of a Graphene-Coated Kerr Slab

et al. 2015

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We study analytically propagating surface plasmon modes of a Kerr slab sandwiched between two graphene layers. We show that some of the modes that propagate forward at low field intensities start propagating with negative slope of dispersion and positive flux of energy (fast-light surface plasmons) when the field intensity becomes high. We also discover that our structure supports an additional branch of low-intensity fast-light guided modes. The possibility of dynamically switching between the forward and the fast-light plasmon modes by changing the intensity of the excitation light or the chemical potential of the graphene layers opens up wide opportunities

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Section: Dispersion Relation For Guided Plasmonsmentioning

confidence: 62%

“…9 of ref. [24] and, thus, Eq. 11 reduces to the dispersion relation of the SPs supported by a simple nonlinear slot waveguide.…”

Section: Dispersion Relation For Guided Plasmonsmentioning

confidence: 95%

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Guided Plasmon Modes of a Graphene-Coated Kerr Slab

et al. 2015

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“…This type of nano-grating or nano-rod structure performs as a single layer AR coating, whereas the triangular (such as, conical or perfect cone) and parabolic shaped nano-grating structures are performing as a multilayer broadband AR coating [3][4][5][6][7][8]. There are some other reports found in the literature related to improving the optical gain in solar cell systems, including surface plasmon resonance-based multilayer structures and also a new design of GaAs solar cells [9][10][11][12].…”

Section: Introductionmentioning

confidence: 99%

“…In this paper, a finite-difference time domain (FDTD) simulation tool is used to simulate the reflection losses for different types of nano-grating structures or shapes [9][10][11][16][17][18][19][20][21][22]. We have considered the following nano-grating profiles: (i) rectangular-; (ii) trapezoidal (i.e., truncated cone or hatch top)-; and (iii) triangular (i.e., conical or perfect cone)-shaped, which is used for the simulation.…”

Section: Introductionmentioning

confidence: 99%

Design and Analysis of Nano-Structured Gratings for Conversion Efficiency Improvement in GaAs Solar Cells

Das

Islam

2016

Energies

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This paper presents the design and analysis of nano-structured gratings to improve the conversion efficiency in GaAs solar cells by reducing the light reflection losses. A finite-difference time domain (FDTD) simulation tool is used to design and simulate the light reflection losses of the subwavelength grating (SWG) structure in GaAs solar cells. The SWG structures perform as an excellent alternative antireflective (AR) coating due to their capacity to reduce the reflection losses in GaAs solar cells. It allows the gradual change in the refractive index that confirms an excellent AR and the light trapping properties, when compared with the planar thin film structures. The nano-rod structure performs as a single layer AR coating, whereas the triangular (i.e., conical or perfect cone) and parabolic (i.e., trapezoidal/truncated cone) shaped nano-grating structures perform as a multilayer AR coating. The simulation results confirm that the reflection loss of triangular-shaped nano-grating structures having a 300-nm grating height and a 830-nm period is about 2%, which is about 28% less than the flat type substrates. It also found that the intermediate (i.e., trapezoidal and parabolic)-shaped structures, the light reflection loss is lower than the rectangular shaped nano-grating structure, but higher than the triangular shaped nano-grating structure. This analysis confirmed that the triangular shaped nano-gratings are an excellent alternative AR coating for conversion efficiency improvement in GaAs solar cells.

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Evolution of surface plasmon–polariton wave in a thin metal film: The modulation‐instability effect

et al. 2016

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The modulation instability development of intensive surface plasmon-polariton waves in a thin metal film is studied. It is shown both analytically and numerically that the modulation-instability effect can give rise to spatial redistribution and longitudinal localization of surface plasmonpolariton wave energy on the subwavelength scale. Analytical expressions for the driving parameters of the modulation instability process − nonlinearity and dispersion − are derived. The impact of the film thickness and dielectric permittivities of constituents on the dynamics of surface plasmon-polariton wave transformation is considered. Numerical simulations show that in the layer structure comprising a silver film of subwavelength thickness a train of subpicosecond optical pulses with high repetition rate can be generated.

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Dispersion relation for surface plasmon polaritons in metal/nonlinear-dielectric/metal slot waveguides

Cited by 45 publications

References 9 publications

Guided Plasmon Modes of a Graphene-Coated Kerr Slab

Guided Plasmon Modes of a Graphene-Coated Kerr Slab

Design and Analysis of Nano-Structured Gratings for Conversion Efficiency Improvement in GaAs Solar Cells

Evolution of surface plasmon–polariton wave in a thin metal film: The modulation‐instability effect

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