High speed plasmonic modulator array enabling dense optical interconnect solutions

Heni, Wolfgang; Hoessbacher, Claudia; Haffner, Christian; Fedoryshyn, Yuriy; Baeuerle, Benedikt; Josten, Arne; Hillerkuss, D.; Salamin, Yannick; Bonjour, Romain; Melikyan, Argishti; Kohl, Manfred; Elder, Delwin L.; Dalton, Larry R.; Hafner, Christian; Leuthold, Juerg

doi:10.1364/oe.23.029746

Cited by 49 publications

(32 citation statements)

References 37 publications

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“…Although silicon nitride is a flexible material [57], [58], it exhibits different challenges that need to be addressed such as its lack modulation mechanism. This situation has driven interest in hybrid silicon photonic devices in which optical functionality is provided by a secondary material, such as 2D materials [59], liquid crystals [60], metals [61], electrooptic polymers [62] [63], germanium [64], and optical phase change materials [PCMs] [65]- [67]. This section presents the large scale integration of novel materials on SiN devices including experimental work integrating O-PCMs for a variety of functionalities.…”

Section: Novel Materials Integrationmentioning

confidence: 99%

Silicon Nitride Photonics for the Near-Infrared

Bucio

Lacava

Clementi

et al. 2020

IEEE J. Select. Topics Quantum Electron.

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In recent years, silicon nitride has drawn attention for the realisation of integrated photonic devices due to its fabrication flexibility and advantageous intrinsic properties that can be tailored to fulfill the requirements of different linear and non-linear photonic applications. This paper focuses on our progress in the demonstration of enhanced functionalities in the near infrared wavelength regime with our low temperature (<350 • C) SiN platform. It discusses (de)multiplexing devices, nonlinear all optical conversion, photonic crystal structures, the integration with novel phase change materials, and introduces applications in the 2 µm wavelength range.

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Section: Novel Materials Integrationmentioning

confidence: 99%

Silicon Nitride Photonics for the Near-Infrared

Bucio

Lacava

Clementi

et al. 2020

IEEE J. Select. Topics Quantum Electron.

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“…Short phase shifters (5 μm) display low optical losses, but require relatively high U π voltages of 10 V causing an electrical energy consumption of 25 fJ/bit [31]. Contrarily, long phase shifters (>10 μm) enable reduced U π voltages at the cost of higher modulator losses [44][45][46]. A way to reduce the driving voltage without suffering from higher losses is to make use of material resonances given by the OEO-material and by gold.…”

Section: Plasmonic-organic Hybrid Modulatorsmentioning

confidence: 99%

“…This configuration allows to achieve a π−phase shift between both arms of the modulator by applying a U π on one arm and a -U π on the other arm in modulator with half the length. Lossvoltage-length products of 25 dBV (12.5 dBV) can then be reached for a simple phase shifter (push-pull Mach-Zehnder Modulator [24,31,43,44,46]). This means POH Mach-Zehnder modulators of 4μm length can be switched from on-state to off-state by a driving voltage of ± 1.5 V with insertion losses of 4 dB only.…”

Section: Simulation Of the Poh Modulator Performance Enhancementmentioning

confidence: 99%

Harnessing nonlinearities near material absorption resonances for reducing losses in plasmonic modulators

Haffner¹,

Heni²,

Elder³

et al. 2017

Opt. Mater. Express

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The electro-optic coefficient (Pockels coefficient) is largest around the absorption resonance of a material. Here, we show that the overall losses, the power consumption and the footprint of plasmonic electro-optic modulators can be reduced when a device is operated in the vicinity of absorption resonances of an electro-optical material. This near-resonant operation in plasmonics is contrary to what is known from photonics where off-resonant operation is required to minimize the overall losses. The findings are supported by experiments demonstrating a reduction in voltage-length product by a factor of 3 and a reduction in loss by a factor 2 when operating a plasmonic modulator near resonance compared to off-resonant.

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“…To take full advantage of this fabrication process, the lateral sizes of the optical and photonic devices should be scaled down to nanometers to be comparable with the process' electronic-scale standard. This can be achieved by using plasmonic technology, which enables the fabrication of these devices with a subwavelength scale, while the diffraction limit is overcome by confinement of light waves at the metal-dielectric interface [22][23][24]. Different structures of lasers [25], waveguides [26], photodetectors [27][28][29], optical modulators [30,31], and optical switches [32,33] have been implemented in different material systems using plasmonic technology.…”

Section: Introductionmentioning

confidence: 99%

Design Investigation of 4 × 4 Nonblocking Hybrid Plasmonic Electrooptic Switch

2019

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This paper proposes a compact, plasmonic-based 4 × 4 nonblocking switch for optical networks. This device uses six 2 × 2 plasmonic Mach-Zehnder switch (MZS), whose arm waveguide is supported by a JRD1 polymer layer as a high electro-optic coefficient material. The 4 × 4 switch is designed in COMSOL environment for 1550 nm wavelength operation. The performance of the proposed switch outperforms those of conventional (nonplasmonic) counterparts. The designed switch yields a compact structure ( 500 × 70 µ m 2 ) having V π L = 12 V · µ m , 1.5 THz optical bandwidth, 7.7 dB insertion loss, and −26.5 dB crosstalk. The capability of the switch to route 8 × 40 Gbps WDM signal is demonstrated successfully.

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High speed plasmonic modulator array enabling dense optical interconnect solutions

Cited by 49 publications

References 37 publications

Silicon Nitride Photonics for the Near-Infrared

Silicon Nitride Photonics for the Near-Infrared

Harnessing nonlinearities near material absorption resonances for reducing losses in plasmonic modulators

Design Investigation of 4 × 4 Nonblocking Hybrid Plasmonic Electrooptic Switch

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