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Roux, Xavier Le
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Publications (9/9 displayed)
- 2023Controlling the Modal Confinement in Silicon Nanophotonic Waveguides through Dual‐Metamaterial Engineeringcitations
- 202040 Gbps heterostructure germanium avalanche photo receiver on a silicon chipcitations
- 2020Third Order Nonlinear Optical Susceptibility of Crystalline Oxide Yttria-Stabilized Zirconiacitations
- 2020Silicon-germanium receivers for short-waveinfrared optoelectronics and communications High-speed silicon-germanium receivers (invited review)citations
- 2019Nonlinear third order silicon photonics enabled by dispersion and subwavelength engineeringcitations
- 2018High-quality crystalline yttria-stabilized-zirconia thin layer for photonic applicationscitations
- 2017Functional oxides on Silicon and Sapphire substrates for photonic applications
- 2016Functional oxides on Silicon and Sapphire substrates for photonic applications
- 2016Oxides on Silicon and Sapphire substrates for photonic applications
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document
Nonlinear third order silicon photonics enabled by dispersion and subwavelength engineering
Abstract
Integrated photonics has for several years included in its panoply the development of functions based on third-order non-linear optical phenomena, from the generation of supercontinuum or frequency comb sources to metrology or spectroscopy on chip applications. This natural evolution, after the development of high-speed transceivers in the last few years, particularly in silicon photonics, is based on a number of compromises and still has to solve problems, particularly concerning the integration of nonlinear materials on silicon and their exploitation. The work we present addresses two directions. The first is oriented towards the development of a supercontinuum source using Nitrogen-rich photonic circuits from an industrial CMOS platform, while the second aims at the development of hybrid highly nonlinear waveguides significantly reducing the impact of twophoton absorption in the telecom window around 1,55µm by exploiting silicon slot waveguides infiltrated by chalcogenide glasses (As2S3).