Stimulated degenerate four-wave mixing in Si nanocrystal waveguides

Manna, Santanu; Bernard, Martino; Biasi, Stefano; Ramiro‐Manzano, Fernando; Mancinelli, Mattia; Ghulinyan, Mher; Pucker, G.; Pavesi, L.

doi:10.1088/2040-8978/18/7/075801

Cited by 7 publications

(1 citation statement)

References 32 publications

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“…In order to have an integrated platform with components working from visible to MIR, the use of non-linear frequency conversion processes based on silicon is crucial, and exploits the advantages of a well-established technology, providing scalability and cost reduction. In particular, the latest studies report non-linear frequency up-conversion in quasi-phase-matched (QPM) Si-based WGs [27][28][29][30][31][32][33][34][35], particularly second-harmonic generation (SHG) and sum-frequency generation (SFG) [36,37]. Recent experiments with Si-based devices reported non-linear generation with output powers above the nW range [38][39][40].…”

Section: Introductionmentioning

confidence: 99%

Silicon-Based Multilayer Waveguides for Integrated Photonic Devices from the Near to Mid Infrared

Garcia¹,

Cumis

Mazzotti³

et al. 2021

Applied Sciences

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Advancements in spectroscopy, quantum optics, communication, and sensing require new classes of integrated photonic devices to host a wide range of non-linear optical processes involving wavelengths from the visible to the infrared. In this framework, waveguide (WG) structures designed with innovative geometry and materials can play a key role. We report both finite element modeling and experimental characterization of silicon nitride multilayer WGs from the visible to the mid-infrared spectral regions. The simulations evaluated optical behavior and mechanical stress as a function of number of WG layers and photonic structure dimensions. WGs were optimized for waveguiding at 1550 nm and 2640 nm. Experimental characterization focused on optical behavior and coupling losses from 532 nm to 2640 nm. Measured losses in WGs indicate a quasi-perfect waveguiding behavior in the IR range (with losses below 6 dB), with a relevant increase (up to 20 dB) in the visible range.

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Section: Introductionmentioning

confidence: 99%

Silicon-Based Multilayer Waveguides for Integrated Photonic Devices from the Near to Mid Infrared

Garcia¹,

Cumis

Mazzotti³

et al. 2021

Applied Sciences

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Silicon nanocrystal slab optical waveguide by multi-energy ion implantation: Linear and nonlinear optical properties

Lizarraga-Medina,

Can-Uc,

Oliver

et al. 2024

Optics Communications

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Review on optical nonlinearity of group-IV semiconducting materials for all-optical processing

Cheng

Wang

et al. 2022

APL Photonics

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Group-IV semiconductor compounds with intense optical nonlinearity have emerged as a new branch of all-optical processing materials benefiting from the manufacturing compatibility with silicon electronic and photonic integrated circuits. Owing to the chemical reforming on the bonding or precipitating feature of the compositional atoms in the membrane matrix, either the orbital hybridization or the quantum self-assembly of interstitial composites can be employed to reform the electronic and optical characteristics. The recent development on enhancing the nonlinear refractive indices of the group-IV semiconductor materials has revealed significant progress to accelerate the all-optical switching logic, which reduces the energy consumption to enable the constitution of the advanced multi-logic gating and the entry-level photonic computing circuits. This work not only overviews the Group-IV semiconductor photonic data processing elements but also prospects for the future direction of optical quantum computation and communication. To date, the nonlinear refractive indices of the group-IV semiconductor materials can be obtained as 10-8-10-16 cm2/W in the range between 300 nm to 10000 nm in 2022. The wavelength conversion and data switching with bit rate beyond 25 Gbps have been achieved via nonlinear photonic waveguide components. By taking the SiC-made micro-ring waveguide as an example, the n2 as high as 3.05×10-14 cm2/W of the resonant SiC micro-ring gate is retrieved from the pump-probe analysis. All-optical data processing including both wavelength switching and format conversion in the highly nonlinear optical SiC waveguide resonator can achieve error-free operation with corresponding bit-error-ratios of lower than 1×10-5 at 25 Gbps after forward error correction.

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Stimulated degenerate four-wave mixing in Si nanocrystal waveguides

Cited by 7 publications

References 32 publications

Silicon-Based Multilayer Waveguides for Integrated Photonic Devices from the Near to Mid Infrared

Silicon-Based Multilayer Waveguides for Integrated Photonic Devices from the Near to Mid Infrared

Silicon nanocrystal slab optical waveguide by multi-energy ion implantation: Linear and nonlinear optical properties

Review on optical nonlinearity of group-IV semiconducting materials for all-optical processing

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