All-optical switching in silicon photonic waveguides with an epsilon-near-zero resonant cavity [Invited]

Neira, Andres D.; Wurtz, Gregory A.; Zayats, Anatoly V.

doi:10.1364/prj.6.0000b1

Cited by 25 publications

(19 citation statements)

References 37 publications

(61 reference statements)

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“…Similar all-optical switching arrangements are based on Mach-Zehnder interferometry [101,102]. Other schemes make use of semiconductor nanoparticles [103][104][105], nanoplasmonic waveguides [106][107][108][109], fiber Bragg gratings [110][111][112] or nanocavities in photonic crystals to strongly enhance optical nonlinearities [113,114]. Moreover, based on irradiation of rubidium vapor, there is a development that uses counter-propagating laser beams to induce an optical pattern that rotates on application of a switching laser [115].…”

Section: Discussionmentioning

confidence: 99%

Off-Resonance Control and All-Optical Switching: Expanded Dimensions in Nonlinear Optics

Forbes

Andrews

2019

Applied Sciences

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The theory of non-resonant optical processes with intrinsic optical nonlinearity, such as harmonic generation, has been widely understood since the advent of the laser. In general, such effects involve multiphoton interactions that change the population of each input optical mode or modes. However, nonlinear effects can also arise through the input of an off-resonant laser beam that itself emerges unchanged. Many such effects have been largely overlooked. Using a quantum electrodynamical framework, this review provides detail on such optically nonlinear mechanisms that allow for a controlled increase or decrease in the intensity of linear absorption and fluorescence and in the efficiency of resonance energy transfer. The rate modifications responsible for these effects were achieved by the simultaneous application of an off-resonant beam with a moderate intensity, acting in a sense as an optical catalyst, conferring a new dimension of optical nonlinearity upon photoactive materials. It is shown that, in certain configurations, these mechanisms provide the basis for all-optical switching, i.e., the control of light-by-light, including an optical transistor scheme. The conclusion outlines other recently proposed all-optical switching systems.

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Section: Discussionmentioning

confidence: 99%

Off-Resonance Control and All-Optical Switching: Expanded Dimensions in Nonlinear Optics

Forbes

Andrews

2019

Applied Sciences

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“…From the applied point of view, the major question is how to organize the interaction in the most efficient way. Many theoretical [57][58][59][60][61][62] and experimental [63][64][65][66][67][68] research works were focused on the models of plasmonic modulators. The HPWG concept and ENZ effect described above are two of the most promising plasmonic solutions which are implemented in different forms and combinations in these models.…”

Section: Building Blocks Of Hybrid Integrated Circuitsmentioning

confidence: 99%

Towards Deep Integration of Electronics and Photonics

2019

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A combination of computational power provided by modern MOSFET-based devices with light assisted wideband communication at the nanoscale can bring electronic technologies to the next level. Obvious obstacles include a size mismatch between electronic and photonic components as well as a weak light–matter interaction typical for existing devices. Polariton modes can be used to overcome these difficulties at the fundamental level. Here, we review applications of such modes, related to the design and fabrication of electro–optical circuits. The emphasis is made on surface plasmon-polaritons which have already demonstrated their value in many fields of technology. Other possible quasiparticles as well as their hybridization with plasmons are discussed. A quasiparticle-based paradigm in electronics, developed at the microscopic level, can be used in future molecular electronics and quantum computing.

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“…Since the early work of L J Hornbeck on the DMD Digital Micromirror Device [4], several modulation and switching effects have been evaluated and applied for spatial light modulators as reviewed in [5]. Recently, radically new physical switching effects have been explored -that cannot be reviewed here -such as alloptical modulation/switching in a silicon waveguide containing highly nonlinear metal nanorods in their epsilon-near-zero regime [6], or else, in the THz range, transmittance modulation is obtained at the charge transfer plasmon frequency by electrically tuning the conductivity of a metasurface composed of graphene islands between metallic blocks [7].…”

Section: Introductionmentioning

confidence: 99%

Nanometer-sensitive wideband opto-mechanical switching concept

2022

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The present paper is concerned with the mechanically extremely sensitive reflection switching concept of a free-space wave impinging on an array of dielectric or semiconductor pillars. Splitting the pillars of a 2D periodic array in its resonant reflection regime at a prescribed wavelength into two parts with a low-index gap of a few nanometers between parts cancels the reflection of a plane wave under normal incidence. The underlying principle lies in the strong and abrupt discontinuity of the electric field component parallel to the pillar axes caused by the gap. The electromagnetic field distribution is consequently deeply perturbed and no longer corresponds to that of an optical resonance of the array; this suppresses the reflection. The electromagnetic analysis of a silicon pillar array leads to the design of a gapless experimental model fabricated by microsystem technologies that exhibits a broad reflection maximum of a few tens of nm at a prescribed wavelength in the visible and near-IR range, and of a pillar structure with nanometer-thick low-index gap exhibiting no reflection peak over this wide wavelength range. A transmission ratio of 1:30 at a 1080 nm peak wavelength between a gapless and a 1.5 index, 30 nm-thick gap structures was measured.

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All-optical switching in silicon photonic waveguides with an epsilon-near-zero resonant cavity [Invited]

Cited by 25 publications

References 37 publications

Off-Resonance Control and All-Optical Switching: Expanded Dimensions in Nonlinear Optics

Off-Resonance Control and All-Optical Switching: Expanded Dimensions in Nonlinear Optics

Towards Deep Integration of Electronics and Photonics

Nanometer-sensitive wideband opto-mechanical switching concept

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