Nonlinear Dynamics of Ultrashort Long-Range Surface Plasmon Polariton Pulses in Gold Strip Waveguides

Lysenko, Oleg; Bache, Morten; Olivier, Nicolas; Zayats, Anatoly V.; Lavrinenko, Andrei V.

doi:10.1021/acsphotonics.6b00509

Cited by 29 publications

(45 citation statements)

References 47 publications

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“…Kerr‐type nonlinearities, which are predominately determined by heating of the electron gas (its energy redistribution in a conduction band), strongly depend on the energy supplied by the light to the electron plasma and, therefore, are strongly affected by the pulse energy and duration in terms of their values and time‐response, varying over several orders of magnitude . They also may depend on the size of the particles and thickness of a metal layer due to modification of the electron scattering rate in nanostructures …”

Section: Plasmonic Metals As Nonlinear Materialsmentioning

confidence: 99%

“…The nonlinear response described by the two‐temperature model depends on the excitation and probe pulse durations if they are comparable to the characteristic times of the electron relaxation processes . The excitation pulse is absorbed by the metal almost instantaneously so that the mean absorbed power density follows the shape of the incident pulse ( Figure ).…”

Section: Plasmonic Metals As Nonlinear Materialsmentioning

confidence: 99%

“…P and

Δ T_{e}

are ultimately directly connected through the electron‐temperature transient response function

h_{T}

Section: Plasmonic Metals As Nonlinear Materialsmentioning

confidence: 99%

“…[57] They also may depend on the size of the particles and thickness of a metal layer due to modification of the electron scattering rate in nanostructures. [58][59][60] Both coherent and Kerr-type nonlinearities of metals may originate from several families of physical effects. One is related to the nonlinear dynamics of the free carriers plasma and is present in all spectral ranges.…”

Section: Plasmonic Metals As Nonlinear Materialsmentioning

confidence: 99%

“…The nonlinear response described by the two-temperature model depends on the excitation and probe pulse durations if they are comparable to the characteristic times of the electron relaxation processes. [58] The excitation pulse is absorbed by the metal almost instantaneously so that the mean absorbed power density follows the shape of the incident pulse (Figure 3). The rise of the thermalised electron energy density is delayed by 100s of fs as the hot electrons release their energy and thermalise with a characteristic time determined by electron-electron and electronphonon scattering rates.…”

Section: Kerr-type Nonlinearity Of Metals: Thermal Response Of Fermiomentioning

confidence: 99%

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Free‐electron Optical Nonlinearities in Plasmonic Nanostructures: A Review of the Hydrodynamic Description

Krasavin

Ginzburg

Zayats

2017

Laser & Photonics Reviews

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Requirements of integrated photonics and miniaturisation of optical devices demand efficient nonlinear components not constrained by conventional macroscopic nonlinear crystals. Intrinsic nonlinear response of free carriers in plasmonic materials provides opportunities to design both second-and third-order nonlinear optical properties of plasmonic nanostructures and control light with light using Kerr-type nonlinearities as well as achieve harmonic generation. This review summarises principles of free-carrier nonlinearities in the hydrodynamic description in both perturbative and non-perturbative regimes, considering also contribution of nonlocal effects. Engineering of harmonic generation, solitons, nonlinear refraction and ultrafast all-optical switching in plasmonic nanostructures and metamaterials are discussed. The full hydrodynamic consideration of nonlinear dynamics of free carriers reveals key contributions to the nonlinear effects defined by the interplay between a topology of the nanostructure and nonlinear response of the fermionic gas at the nanoscale, allowing design of high effective nonlinearities in a desired spectral range. Flexibility and unique features of free-electron nonlinearities are important for nonlinear plasmonic applications in free-space as well as integrated and quantum nanophotonic technologies.

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Section: Plasmonic Metals As Nonlinear Materialsmentioning

confidence: 99%

Section: Plasmonic Metals As Nonlinear Materialsmentioning

confidence: 99%

“…P and

Δ T_{e}

are ultimately directly connected through the electron‐temperature transient response function

h_{T}

Section: Plasmonic Metals As Nonlinear Materialsmentioning

confidence: 99%

Section: Plasmonic Metals As Nonlinear Materialsmentioning

confidence: 99%

Section: Kerr-type Nonlinearity Of Metals: Thermal Response Of Fermiomentioning

confidence: 99%

See 3 more Smart Citations

Free‐electron Optical Nonlinearities in Plasmonic Nanostructures: A Review of the Hydrodynamic Description

Krasavin

Ginzburg

Zayats

2017

Laser & Photonics Reviews

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Geometry Defines Ultrafast Hot‐Carrier Dynamics and Kerr Nonlinearity in Plasmonic Metamaterial Waveguides and Cavities

Peruch

Neira

Wurtz

et al. 2017

Advanced Optical Materials

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as nonlinear optical response of plasmonic nanostructures and its temporal dynamics. [1] Illumination of a material containing free electrons results in a redistribution of the electrons between allowed energy states within the conduction band either due to interband transitions and/ or intraband transitions facilitated by phonons or surface plasmons, depending on the illumination wavelength. The excitation by a short light pulse, generally results in the nonthermalized distribution of free electrons in the conduction band (or holes in the valence bands, depending on the excitation wavelength and band structure of the material). Relatively fast electron-electron and electron-phonon scattering processes establish the thermalized electron distribution described by the increased temperature, before the residual electron energy is transferred to lattice.A reliable way to probe the electron distribution modifications and its dynamics is based on optical pump-probe spectroscopy, allowing to trace in time nonlinear optical modifications of the permittivity of the material induced by the absorption of a strong short pulse with a weak probe light. The excitation of nonequlibrium electrons results in the modifications of the permittivity of plasmonic metals, which leads to nonlinear changes of absorption and scattering of plasmonic nanoparticles. When such nanoparticles are assembled in metamaterials-composite nanostructured media that exhibit effective optical properties at the macroscopic level-controlling the interaction between the metamaterial's constituents affects both linear optical properties and nonlinear response as well as its dynamics associated with the excitation and relaxation of the electron gas. [2] Plasmonic metamaterials can be understood considering "meta-atoms" capable of supporting coherent electron gas excitations with high light-matter interaction strength. They are widely used for engineering refraction and reflection properties, as bio and chemical sensing components as well as for actively controlling light. [3] The strong field enhancement provided by plasmonic modes facilitates nonlinear light-matter interactions at relatively low light intensities, including the optical Kerr effect which leads to light-induced nonlinear changes in Hot carrier dynamics in plasmonic nanorod metamaterials and its influence on the metamaterial's optical Kerr nonlinearity is studied. The electron temperature distribution induced by an optical pump in the metallic component of the plasmonic metamaterial leads to geometry-dependent variations of the optical response and its dynamics as observed in both the transmission and reflection properties of the metamaterial slab. Thus, the ultrafast dynamics of a metamaterial's optical response can be controlled via modal engineering. Both the transient response relaxation time and magnitude of the nonlinearity are shown to depend on the modal-induced spatial profile of the electron temperature distribution and the hot-electron diffusion in nanorods. The nonlocal effects, ...

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Multitasking Shared Aperture Enabled with Multiband Digital Coding Metasurface

Bai

Iqbal

et al. 2018

Advanced Optical Materials

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Digital coding metasurface is aimed at building up a bridge between physics and information science. Higher information capacity of the digital coding metasurface means more powerful ability to control electromagnetic waves. Here, a multiband digital coding metasurface to improve the information capacity is proposed. The digital coding structures can provide 2‐bit digital states at three separate frequency bands (C, X, and Ku). It is shown that the proposed metasurface can eliminate the in‐band interference and path degradation by introducing an operator of frequency‐hopping spread spectra, from which flexible beam controls can be designed independently in every operating band. To demonstrate the capability and the compatibility, a multifunctional digital coding metasurface which can perform optical illusion, scattering reduction, and generation of orbital angular momentum in a shared aperture is presented. Numerical simulations and measured results have very good agreements, verifying excellent performance of the multiband digital coding metasurface. The proposed method opens opportunities to improve the information capacity of the digital coding metasurface and paves novel ways to multitasking systems on photonic applications.

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Nonlinear Dynamics of Ultrashort Long-Range Surface Plasmon Polariton Pulses in Gold Strip Waveguides

Cited by 29 publications

References 47 publications

Free‐electron Optical Nonlinearities in Plasmonic Nanostructures: A Review of the Hydrodynamic Description

Free‐electron Optical Nonlinearities in Plasmonic Nanostructures: A Review of the Hydrodynamic Description

Geometry Defines Ultrafast Hot‐Carrier Dynamics and Kerr Nonlinearity in Plasmonic Metamaterial Waveguides and Cavities

Multitasking Shared Aperture Enabled with Multiband Digital Coding Metasurface

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