Periodic Reporting for period 4 - POPSTAR (Low power consumption silicon optoelectronics based on strain and refractive index engineering)
Período documentado: 2020-04-01 hasta 2020-09-30
In this silicon photonics ecosystem, the POPSTAR project will address a new route to make key advances in the development of low power consumption multi-wavelength high-speed communication circuits based on second- and third-order nonlinear optical effects in silicon. The original idea of the project is to generate strains in sub-wavelength silicon photonic nano-structures leading to significant breakthroughs in second-order nonlinearities efficiency (Pockels effect) and in third-order nonlinearities.
The second objective was to demonstrate Pockels effect in silicon waveguide. Numerous samples have been fabricated in the host clean room and tested based on the deposition of silicon nitride on the top of the waveguides. Optical modulation results up to 40GHz have then been obtained, which clearly demonstrated the presence of Pockels effect in silicon. Furthermore, an open eye diagram at 10Gbit/s has also been obtained. This promising result opens the route towards the demonstration of high-speed optical modulators in silicon. These promising measurements have been carried out considering silicon nitride (SiN) as a stress layer. It was also demonstrated that SiN is not the best material to act as a stressor due to some fixed charges at the SiN/Si interface. Then, as a third objective, new materials to induce strain in silicon have been explored. First, we developed the epitaxial growth of YSZ (Yttria-stabilized zirconia) on silicon. YSZ is a crystalline oxide with very interesting properties. The optimization of the epitaxial growth has been performed on Sapphire and silicon substrates and good crystalline quality has been obtained. However, the strain induced in silicon is not strong enough, especially due to the formation of an oxide layer at the Si/YSZ interface. We are also studying new materials including AlN and Chalcogenide in collaboration with Aalto Univ. and MIT to induce nonlinear effects and strain in silicon waveguide. Strip and rib waveguides have been designed, fabricated and characterized leading to promising low propagation loss.
During the project, the PI team has also demosntrated outstanding results on photodetectors and avalanche photodiode for high speed communications.
In parallel, some design, fabrication and characterization have been performed on subwavelength silicon structures. The objective here was to demonstrate the versatility of subwavelength structures for dispersion engineering and mode confinement engineering.
To conclude, all these results confirm the great potential of strained silicon photonics for the development of low power consumption and high-speed photonic circuits.
Here below are the main results beyond the state of the art obtained during Popstar project:
- Development of a new model describing Pockels effect in strained materials
- Demonstration of high speed Pockels effect in Si waveguide
- Demonstration of reliable SiGe heterojunction for light detection at 40Gbit/s
- Demonstration of 40Gbit/s avalanche Ge receiver
- Demonstration of Si/SiN photonics devices for wavelength and polarization managing.
- 2 octave supercontinuum in CMOS compatible SiN waveguides
- Ultra-high optical gain in erbium doped YSZ on SiN photonics waveguides
- Low loss crystalline YSZ waveguide
- First demosntration of third order nonlinearity in YSZ waveguides including ab-initio simulations.