Session Overview |
Photonic theory design and simulations - Bloc 1Room: Cartier 1 |
Date: Tuesday, June 05 |
08:00 |
Residual Amplitude Modulation of optical phase modulators
Main Author: Henri Porte Organization: iXblue Photonics, France The paper proposes an interpretation about the residual amplitude modulation (RAM) that can be observed in electro-optic guided wave phase modulators integrating coplanar electrodes, with a good agreement between simulations and experimental observation. |
08:15 |
Integrated Optical Fluid Sensing Using Mid-IR Silicon Photonics
Main Author: Christian Ranacher Organization: Carinthian Tech Research AG, Austria Photonic micro sensors for fluid sensing that operate in the mid-infrared spectral range are an emerging field for silicon photonics. A concept for facilitating fully integrated sensors is presented. |
08:30 |
SOI Doped Waveguide Heaters for In-Situ Defect Annealing
Main Author: David Hagan Organization: McMaster University, Canada We demonstrate an SOI doped heater waveguide platform capable of reaching sufficiently high temperatures for in-situ defect annealing and other localized temperature-sensitive chemistry. |
08:45 |
Spot-size converters with shaped oxide cladding
Main Author: Huai Yang Organization: McGill University, Canada A novel spot-size converter without polymer deposition is presented. Simulation results shows a coupling loss of 2.3/2.8 dB for TE/TM at 1550 nm with an optical bandwidth greater than 300 nm. |
09:00 |
Ge implantation into silicon for trimming, wafer scale testing and programmable photonics
Main Author: Graham T. Reed Organization: University of Southampton, United Kingdom To be announced |
09:45 |
III-V silicon integration
Main Author: Dries Van Thourhout Organization: Ghent University, Belgium To be announced |
10:10 |
Design of Photonic Structures for High Efficiency Nanowire Quantum Dot Emitters
Main Author: Dan Dalacu Organization: National Research Council of Canada, Canada Quantum dots in position-controlled nanowires have demonstrated optical properties comparable to state-of-the-art devices based on self-assembled quantum dots. These properties include near-lifetime limited linewidths, low multiphoton emission probabilities, and high fidelity polarization entangled photon pair generation. In this presentation we address strategies to efficiently collect the emission from nanowire quantum dots, both as-grown and on-chip. In particular, we identify photonic structures with near-unity collection efficiencies and propose a methodology to achieve deterministic on-chip integration using these structures. |