Your search keyword '"Cecilia Dupre"' showing total 5 results

1. AlGaInAs Multi-Quantum Well Laser Array on Silicon Achieved by InP-Seed-Bonding and MOVPE Selective Area Growth

Author

Claire Besancon, Nicolas Vaissiere, Delphine Neel, Hussein Mehdi, Gauthier Lefevre, Viviane Muffato, Loic Sanchez, Frank Fournel, Cecilia Dupre, Franck Bassani, and Jean Decobert

Published

2022

2. Metamaterial-Engineered Silicon Beam Splitter Fabricated with Deep UV Immersion Lithography

Author

Laurent Vivien, Xavier Le Roux, Vladyslav Vakarin, Thi Thuy Duong Dinh, Frederic Boeuf, Eric Cassan, Carlos Alonso-Ramos, Cecilia Dupre, Bertrand Szelag, Warren Kut King Kan, Pavel Cheben, Delphine Marris-Morini, Daniele Melati, and Stephane Monfray

Subjects

Materials science, Fabrication, General Chemical Engineering, Physics::Optics, Grating, metamaterial, beam splitter, Article, subwavelength grating, law.invention, law, Hardware_INTEGRATEDCIRCUITS, General Materials Science, Lithography, QD1-999, Immersion lithography, Electronic circuit, Silicon photonics, silicon photonics, business.industry, Metamaterial, Chemistry, multi-mode interference coupler, Optoelectronics, business, Beam splitter

Abstract

Subwavelength grating (SWG) metamaterials have garnered a great interest for their singular capability to shape the material properties and the propagation of light, allowing the realization of devices with unprecedented performance. However, practical SWG implementations are limited by fabrication constraints, such as minimum feature size, that restrict the available design space or compromise compatibility with high-volume fabrication technologies. Indeed, most successful SWG realizations so far relied on electron-beam lithographic techniques, compromising the scalability of the approach. Here, we report the experimental demonstration of an SWG metamaterial engineered beam splitter fabricated with deep-ultraviolet immersion lithography in a 300-mm silicon-on-insulator technology. The metamaterial beam splitter exhibits high performance over a measured bandwidth exceeding 186 nm centered at 1550 nm. These results open a new route for the development of scalable silicon photonic circuits exploiting flexible metamaterial engineering.

Published

2021

3. Characterisation and modelling of nonlinear resonance behaviour on very-high-frequency silicon nanoelectromechanical resonators

Author

Fang Ben, James Fernando, Jun-Yu Ou, Cécilia Dupré, Eric Ollier, Faezeh Arab Hassani, Hiroshi Mizuta, and Yoshishige Tsuchiya

Subjects

Nanoelectromechanical systems, Nonlinear resonance, Mixing measurements, Duffing oscillator equation, Electronics, TK7800-8360, Technology (General), T1-995

Abstract

This paper reports a novel method to build a model for nonlinear resonance behaviour of very-high-frequency (VHF) silicon nanoelectromechanical (NEM) resonators, measured via 1-ω mixing resonance measurements. Systematic fitting results for the experimental data of a 1.5-μm-long beams have been achieved with explicit explanation of the amount of intrinsic mechanical nonlinearity and nonlinear voltage-tuning effect. Asymmetric line shape and onset of hysteresis on nonliner resonance behavour have been well demonstrated with less fitting errors. The development of a modelling method of nanoscale resonator devices which includes nonlinear response is beneficial for seamless technology transfer from individual devices to integrated systems in the future.

Published

2023

4. AlGaInAs Multi-Quantum Well Lasers on Silicon-on-Insulator Photonic Integrated Circuits Based on InP-Seed-Bonding and Epitaxial Regrowth

Author

Claire Besancon, Delphine Néel, Dalila Make, Joan Manel Ramírez, Giancarlo Cerulo, Nicolas Vaissiere, David Bitauld, Frédéric Pommereau, Frank Fournel, Cécilia Dupré, Hussein Mehdi, Franck Bassani, and Jean Decobert

Subjects

heterogeneous integration, epitaxial growth, direct wafer bonding, semiconductor lasers, silicon photonics, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

The tremendous demand for low-cost, low-consumption and high-capacity optical transmitters in data centers challenges the current InP-photonics platform. The use of silicon (Si) photonics platform to fabricate photonic integrated circuits (PICs) is a promising approach for low-cost large-scale fabrication considering the CMOS-technology maturity and scalability. However, Si itself cannot provide an efficient emitting light source due to its indirect bandgap. Therefore, the integration of III-V semiconductors on Si wafers allows us to benefit from the III-V emitting properties combined with benefits offered by the Si photonics platform. Direct epitaxy of InP-based materials on 300 mm Si wafers is the most promising approach to reduce the costs. However, the differences between InP and Si in terms of lattice mismatch, thermal coefficients and polarity inducing defects are challenging issues to overcome. III-V/Si hetero-integration platform by wafer-bonding is the most mature integration scheme. However, no additional epitaxial regrowth steps are implemented after the bonding step. Considering the much larger epitaxial toolkit available in the conventional monolithic InP platform, where several epitaxial steps are often implemented, this represents a significant limitation. In this paper, we review an advanced integration scheme of AlGaInAs-based laser sources on Si wafers by bonding a thin InP seed on which further regrowth steps are implemented. A 3 µm-thick AlGaInAs-based MutiQuantum Wells (MQW) laser structure was grown onto on InP-SiO2/Si (InPoSi) wafer and compared to the same structure grown on InP wafer as a reference. The 400 ppm thermal strain on the structure grown on InPoSi, induced by the difference of coefficient of thermal expansion between InP and Si, was assessed at growth temperature. We also showed that this structure demonstrates laser performance similar to the ones obtained for the same structure grown on InP. Therefore, no material degradation was observed in spite of the thermal strain. Then, we developed the Selective Area Growth (SAG) technique to grow multi-wavelength laser sources from a single growth step on InPoSi. A 155 nm-wide spectral range from 1515 nm to 1670 nm was achieved. Furthermore, an AlGaInAs MQW-based laser source was successfully grown on InP-SOI wafers and efficiently coupled to Si-photonic DBR cavities. Altogether, the regrowth on InP-SOI wafers holds great promises to combine the best from the III-V monolithic platform combined with the possibilities offered by the Si photonics circuitry via efficient light-coupling.

Published

2021

5. Metamaterial-Engineered Silicon Beam Splitter Fabricated with Deep UV Immersion Lithography

Author

Vladyslav Vakarin, Daniele Melati, Thi Thuy Duong Dinh, Xavier Le Roux, Warren Kut King Kan, Cécilia Dupré, Bertrand Szelag, Stéphane Monfray, Frédéric Boeuf, Pavel Cheben, Eric Cassan, Delphine Marris-Morini, Laurent Vivien, and Carlos Alberto Alonso-Ramos

Subjects

subwavelength grating, metamaterial, silicon photonics, multi-mode interference coupler, beam splitter, Chemistry, QD1-999

Abstract

Subwavelength grating (SWG) metamaterials have garnered a great interest for their singular capability to shape the material properties and the propagation of light, allowing the realization of devices with unprecedented performance. However, practical SWG implementations are limited by fabrication constraints, such as minimum feature size, that restrict the available design space or compromise compatibility with high-volume fabrication technologies. Indeed, most successful SWG realizations so far relied on electron-beam lithographic techniques, compromising the scalability of the approach. Here, we report the experimental demonstration of an SWG metamaterial engineered beam splitter fabricated with deep-ultraviolet immersion lithography in a 300-mm silicon-on-insulator technology. The metamaterial beam splitter exhibits high performance over a measured bandwidth exceeding 186 nm centered at 1550 nm. These results open a new route for the development of scalable silicon photonic circuits exploiting flexible metamaterial engineering.

Published

2021