048Tb/s (12x40Gb/s) WDM transmission and high-quality thermo-optic switching in dielectric loaded plasmonics

Kalavrouziotis, D.; Papaioannou, S.; Giannoulis, Giannis; Apostolopoulos, D.; Hassan, Karim; Markey, Laurent; Weeber, Jean-Claude; Dereux, Alain; Kumar, Ashwani; Bozhevolnyi, Sergey I.; Baus, M.; Karl, Matthias; Tekin, Tolga; Tsilipakos, Odysseas; Pitilakis, Alexandros; Kriezis, Emmanouil E.; Avramopoulos, H.; Vyrsokinos, K.; Pleros, Nikos

doi:10.1364/oe.20.007655

Cited by 34 publications

(33 citation statements)

References 24 publications

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“…This approach has potential to yield a power-efficient tunable visible frequency hyperbolic metamaterial with ultrafast (~fs) modulation that is robust and compatible with current optical technology. Potential tuning mechanisms include modifying the complex dielectric function of component materials via phase transitions [27], mechanical deformations [28] as well as electronic mechanisms [29,30] for tuning such as carrier accumulation and depletion [31]. Among these, field effect modulation is particularly attractive because of its robustness and very low power dissipation in steady state.…”

Section: Introductionmentioning

confidence: 99%

Field-effect induced tunability in hyperbolic metamaterials

Papadakis

Atwater

2015

Phys. Rev. B

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We demonstrate that use of the field effect enables tuning of the effective optical parameters of a layered hyperbolic metamaterial at optical frequencies. Field effect gating electrically modulates the permittivity in transparent conductive oxides via changes in the carrier density. These permittivity changes lead to active modulation of the effective electromagnetic parameters along with active control of the anisotropic dispersion surface of hyperbolic metamaterials and enable the opening and closing of photonic band gaps. Tunability of effective electric permittivity and magnetic permeability also leads to topological transitions in the optical dispersion characteristics. KeywordsHyperbolic metamaterials (HMM), isofrequency contour, density of optical states, epsilon near zero (ENZ), epsilon near pole (ENP), field effect, transparent conductive oxide (TCO), indium tin oxide (ITO), metal-oxide-semiconductor (MOS)

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Section: Introductionmentioning

confidence: 99%

Field-effect induced tunability in hyperbolic metamaterials

Papadakis

Atwater

2015

Phys. Rev. B

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“…An interesting finding is that the insertion loss can be about 1-2 dB only; this is not only about an order of magnitude lower compare to~19.8 dB insertion loss obtained by a directional coupler structure [4], but also states that plasmonics is not necessarily a high-loss technology [35]. This denotes that plasmonics can be strategically used to enhance the LMI, if synergistically integrated in passive data routing (i.e.…”

Section: Electro-optic and Spectral Performancementioning

confidence: 93%

A compact plasmonic MOS-based 2×2 electro-optic switch

Liu

Soref

et al. 2015

Nanophotonics

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Abstract:We report on a three-waveguide electro-optic switch for compact photonic integrated circuits and data routing applications. The device features a plasmonic metal-oxide-semiconductor (MOS) mode for enhanced light-matter-interactions. The switching mechanism originates from a capacitor-like design where the refractive index of the active medium, indium-tin-oxide, is altered via shifting the plasma frequency due to carrier accumulation inside the waveguide-based MOS structure. This light manipulation mechanism controls the transmission direction of transverse magnetic polarized light into either a CROSS or BAR waveguide port. The extinction ratio of 18 (7) dB for the CROSS (BAR) state, respectively, is achieved via a gating voltage bias. The ultrafast broadband fJ/bit device allows for seamless integration with silicon-on-insulator platforms for low-cost manufacturing.

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“…The evaluation of the WDM data transmission capabilities of plasmonics is initially carried out via a 60μm-long PMMA-loaded straight waveguide that is included in a Si-plasmonic chip [31], [38]. This chip comprises Si rib waveguides, DLSPP waveguides and Si-to-DLSPP interfaces that follow the specifications presented in Section 2.2 as well as Si TM grating couplers so as to enable optical communication with the outside world.…”

Section: Wdm Data Transmission Through a Dlspp Waveguidementioning

confidence: 99%

“…Another approach for bringing down the consumed power is the utilization of polymer materials with higher TOC value instead of PMMA loadings. For example, Cycloaliphatic acrylate (Cyclomer) exhibits almost three times higher TOC than PMMA and has been already successfully applied as the polymer loading in DLSPP switching structures [34], [38]. Though yet not optimized for lowenergy switching operation, this route is expected to significantly decrease the required energy levels without compromising the switching performance.…”

Section: Optimization Proceduresmentioning

confidence: 99%

“…In this perspective, silicon photonics can be used for low-loss optical transmission in passive interconnection components, plasmonics can provide small footprint and low power consumption in active switching modules and electronics can be employed for intelligent decision-making mechanisms. However, considering that plasmonic technology is a premature technology with only a few years of development compared to silicon photonics and with limited functionality so far, the way towards the implementation of such hybrid NoC environments requires priorly: a) the interconnection between silicon and plasmonic waveguide structures in a SOI platform in order to avoid the employment of high-loss plasmonic waveguides for passive circuitry [30], [37], b) the proof of the credentials of plasmonics in wavelength division multiplexing (WDM) applications so as to support the complete portfolio of optics [38], c) the demonstration of functional active plasmonic circuitries in realistic data traffic environments [25], [31].…”

Section: Introductionmentioning

confidence: 99%

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