Étude et réalisation de sources photoniques intégrées sur InP pour les applications télécoms à hauts débits et à 1,55 µm / Study and fabrication of InP integrated photonic sources for high bit rate telecom applications at 1.55µm

Carrara, David

23 May 2012

Les formats de modulation avancés, codant l’information sur la phase, la polarisation ou plusieurs niveaux d’amplitude de la lumière reçoivent aujourd’hui un intérêt croissant. En effet, ceux-ci permettent d’atteindre une meilleure efficacité spectrale et par conséquent des débits plus élevés. Ces caractéristiques sont actuellement très recherchées dans les télécommunications pour répondre à la demande constante d’augmentation de capacité des transmissions optiques fibrées. L’essentiel du travail effectué porte sur la génération de tels signaux dans des sources photoniques monolithiques sur InP faisant appel à un concept nouveau de commutation de phases optiques préfixées avec des modulateurs électro-absorbants. Une comparaison de notre technologie intégrée avec la technologie actuelle de génération de formats de modulation avancés démontre des possibilités nouvelles de réduction de taille, de diminution de consommation énergétique et d’évolution en vitesse de modulation jusqu’à 56 GBauds. Suite à la validation, par simulations, d’architectures de transmetteurs spécifiques pour la génération de formats de modulation avancés, nous réalisons en salle blanche les circuits photoniques intégrés d’étude. Les caractérisations statiques confirment le fonctionnement de toutes les fonctions intégrées des circuits et soulignent l’efficacité de la filière technologique. Pour une première démonstration de fonctionnalité nous choisissons un transmetteur BPSK capable de générer une modulation de phase à 12,4 GB. Ce résultat démontre la plus petite source intégrée BPSK à l’heure actuelle. Un autre circuit capable de générer des formats de modulation plus complexes est aussi caractérisé / Advanced modulation formats, encoding data on the phase, polarization or multi-level intensity of the light are currently a hot topic in the telecommunication domain. By using them, high spectral efficiency and therefore higher bit rate signals could be generated. Those characteristics are really attractive for the telecommunication systems manufacturers in order to answer to the constant need of increased bandwidth in fiber optic communications. The study of advanced modulation formats generation in Photonic Integrated Circuits (PICs) based on a new concept of preset phases switching by Electro-Absorption Modulators is the main task of the current work. Compared to the actual technology used for generate advanced modulations, our choice could allow a strong reduction of the dimensions and of the energy consumption of the transmitter as well as bit rate up to 56 GB. After validating specific transmitters’ architectures by simulations, we fabricated the studied photonic integrated circuits in clean room. Through static characterizations, we verify that all integrated functions of the transmitters are working and we show the efficiency of our technological choices. Using the available equipments at the lab, we prove the validity of our concept of EAM based phase switching by using a BPSK transmitter. A 12.4 GB BPSK modulation is obtained as well as a wide open eye diagram. This result demonstrates the smallest BPSK integrated photonic source at this time. Another photonic circuit able to generate more complex modulation formats is also measured

Circuit photonique intégré

BPSK

QAM

Format de modulation avancé

InP

Haut débit

QPSK

Modulateur électro-absorbant

Photonic integrated circuit

BPSK

QAM

Advanced modulation format

InP

High bit rate

QPSK

Electro-absorption modulator

Enhancing the Performance of Si Photonics: Structure-Property Relations and Engineered Dispersion Relations

Nikkhah, Hamdam

January 2018

The widespread adoption of photonic circuits requires the economics of volume manufacturing offered by integration technology. A Complementary Metal-Oxide Semiconductor compatible silicon material platform is particularly attractive because it leverages the huge investment that has been made in silicon electronics and its high index contrast enables tight confinement of light which decreases component footprint and energy consumption. Nevertheless, there remain challenges to the development of photonic integrated circuits. Although the density of integration is advancing steady and the integration of the principal components – waveguides, optical sources and amplifiers, modulators, and photodetectors – have all been demonstrated, the integration density is low and the device library far from complete. The integration density is low primarily because of the difficulty of confining light in structures small compared to the wavelength which measured in micrometers. The device library is incomplete because of the immaturity of hybridisation on silicon of other materials required by active devices such as III-V semiconductor alloys and ferroelectric oxides and the difficulty of controlling the coupling of light between disparate material platforms. Metamaterials are nanocomposite materials which have optical properties not readily found in Nature that are defined as much by their geometry as their constituent materials. This offers the prospect of the engineering of materials to achieve integrated components with enhanced functionality. Metamaterials are a class of photonic crystals includes subwavelength grating waveguides, which have already provided breakthroughs in component performance yet require a simpler fabrication process compatible with current minimum feature size limitations. The research reported in this PhD thesis advances our understanding of the structure-property relations of key planar light circuit components and the metamaterial engineering of these properties. The analysis and simulation of components featuring structures that are only just subwavelength is complicated and consumes large computer resources especially when a three dimensional analysis of components structured over a scale larger than the wavelength is desired. This obstructs the iterative design-simulate cycle. An abstraction is required that summarises the properties of the metamaterial pertinent to the larger scale while neglecting the microscopic detail. That abstraction is known as homogenisation. It is possible to extend homogenisation from the long-wavelength limit up to the Bragg resonance (band edge). It is found that a metamaterial waveguide is accurately modeled as a continuous medium waveguide provided proper account is taken of the emergent properties of the homogenised metamaterial. A homogenised subwavelength grating waveguide structure behaves as a strongly anisotropic and spatially dispersive material with a c-axis normal to the layers of a one dimensional multi-layer structure (Kronig-Penney) or along the axis of uniformity for a two dimensional photonic crystal in three dimensional structure. Issues with boundary effects in the near Bragg resonance subwavelength are avoided either by ensuring the averaging is over an extensive path parallel to boundary or the sharp boundary is removed by graded structures. A procedure is described that enables the local homogenised index of a graded structure to be determined. These finding are confirmed by simulations and experiments on test circuits composed of Mach-Zehnder interferometers and individual components composed of regular nanostructured waveguide segments with different lengths and widths; and graded adiabatic waveguide tapers. The test chip included Lüneburg micro-lenses, which have application to Fourier optics on a chip. The measured loss of each lens is 0.72 dB. Photonic integrated circuits featuring a network of waveguides, modulators and couplers are important to applications in RF photonics, optical communications and quantum optics. Modal phase error is one of the significant limitations to the scaling of multimode interference coupler port dimension. Multimode interference couplers rely on the Talbot effect and offer the best in-class performance. Anisotropy helps reduce the Talbot length but temporal and spatial dispersion is necessary to control the modal phase error and wavelength dependence of the Talbot length. The Talbot effect in a Kronig-Penny metamaterial is analysed. It is shown that the metamaterial may be engineered to provide a close approximation to the parabolic dispersion relation required by the Talbot effect for perfect imaging. These findings are then applied to the multimode region and access waveguide tapers of a multi-slotted waveguide multimode interference coupler with slots either in the transverse direction or longitudinal direction. A novel polarisation beam splitter exploiting the anisotropy provided by a longitudinally slotted structure is demonstrated by simulation. The thesis describes the design, verification by simulation and layout of a photonic integrated circuit containing metamaterial waveguide test structures. The test and measurement of the fabricated chip and the analysis of the data is described in detail. The experimental results show good agreement with the theory, with the expected errors due to fabrication process limitations. From the Scanning Electron Microscope images and the measurements, it is clear that at the boundary of the minimum feature size limit, the error increases but still the devices can function.

Silicon Photonics

SOI

Photonic Integrated Circuit (PIC)

Mach-Zehnder Interferometer (MZI)

Lüneburg Lens

Subwavelength Grating (SWG)

Nano-Structured Waveguide Components

Multi-Slotted Waveguide

Metamaterials

Floquet-Bloch Modes

Homogenisation

Photonic Band structure

FDTD

Eigenmode Expansion Method

Kronig-Penney Model

Anisotropy

Modal Phase Error

Polarisation Beam Splitter (PBS)

Talbot Effect in a Metamaterial

Optical Adiabatic Transition

Prototype PIC

Characterisation