Analysis of Waveguide Bending Loss and Quantum-dot Semiconductor Optical Amplifiers

Weng, Tzung-Cheng

17 July 2008

In this thesis, it mainly studies the performance characteristics of the bending losses in semiconductor waveguides and the quantum dots semiconductor optical amplifier. We used InP-subtract and InGaAlAs /InAlAs multiple quantum wells epitaxial wafer grown by MBE as our material(£fg=1.41£gm). We had successfully fabricated a series of bending strip-loaded waveguides. On the quantum dots semiconductor optical amplifier, symmetric InGaAlAs/GaAs quantum well structure is used to fabricate the optical waveguide. We have established an automatic optical measurement system to measure the device characteristics more accurately. Design respect of bending waveguide, we design a series of radius, is 60£gm, 80£gm, 110£gm, 170£gm,and 260£gm respectively, and utilize Fabry-Perot resonant, measurement and estimate the loss of bending waveguide in quantity. We find the bending waveguide loss as radius for 260£gm and contain deeply etching process was quite equal to straight waveguide loss. On the quantum dots semiconductor optical amplifier, we design a single mode waveguide and a broad area waveguide to compare the difference of their electron-hole combination situation. A single mode waveguide with longer cavity length had better combination situation than shorter (C311 of cavity length 4000£gm ,0.00066£gW *A/cm2). And the broad area waveguide had more better combination situation to single mode waveguide (C311 of cavity width 150£gm, length 4000£gm , 0.0966£gW *A/cm2). For the gain to the pump signal, C311 singe mode waveguide (emission peak:1211nm,pump signal:1260nm) could get a gain about 3.56dB¡Fand C374 singe mode waveguide (emission peak:1255nm,pump signal:1260nm) could get a gain about 6.1dB.

transparent current

effective index method

bending loss

Simulation Study of Epitaxially Regrown Vertical-Cavity Surface-Emitting Lasers

Wu, Xiaoyue

January 2011

The vertical-cavity surface-emitting laser or VCSEL is a special type of diode laser, which has established itself in optoelectronic applications asa low-cost, high-quality miniaturized light source. The development of VCSELs can be largely promoted with support from computer simulations. In this study, we have used such simulations, on one hand to understand and improve the VCSEL performance, and on the other hand to prepare for analyzing new device concepts such as transistor-VCSELs. This thesis starts with a background introduction to the principle idea of VCSELs and then states the significance of this simulation work.Then it briefly introduces the previously used simulation workbench Sentaurus and explains the mathematical approach and the computation methods of the finally chosen simulator PICS3D. The case study of a fabricated and characterized epitaxially regrown VCSEL is the major component of this work. First the device configuration is demonstrated with detailed discussion on several design features. Second the physical models of electrical, optical and thermal phenomena along with their key parameters are presented and so are the advanced models for the active region. The main results of simulation, including steady-state characteristics and small-signal modulation, show good agreement with the experimental results and reveal some imperfections of the device design and processing, such as the overestimated stability of the regrown junction and the variation of cavity length caused by over-etch. This work is also treated as an evaluation of the simulator PICS3D, and two problems are identified: one is the troublesome way to construct a 3D device by coupling several 2D layer structures together, requiring the mesh for each layer structure to be compatible; the other would be the tricky boundary setting for the adopted method, Effective Index Method (EIM), for the transverse field calculation when only a weak index guiding effect exits in the cavity. Finally, we summarize this work and suggest some tasks for further simulations.

III-V compound semiconductor

PICS3D

Engineering and Technology

Teknik och teknologier

Análise de dispositivos com materiais magnetoópticos para aplicações em sistemas de comunicações ópticas / not available

Gonçalves, Evandro Assis Costa

21 September 2001

As redes ópticas de comunicação têm possibilitado, cada vez mais, o oferecimento de serviços do tipo faixa larga. A rede de comunicação totalmente óptica está se tornando a meta tecnológica mais ambiciosa. Grandes esforços têm sido concentrados no desenvolvimento e aperfeiçoamento de materiais e dispositivos não-recíprocos, como isoladores e circuladores constituem uma importante classe de dispositivos ópticos. Os isoladores são utilizados em sistemas ópticos para prevenir a reflexão de luz em lasers e amplificadores. Os circuladores são empregados em esquemas de derivação de sinais que utilizam multiplexação em comprimento de onda (WDM). O funcionamento destes dispositivos é baseado nas propriedades de materiais magnetoópticos. As metas desta dissertação são apresentar as principais características dos materiais magnetoópticos, explorando as características não-recíprocas dos modos TM. Guias planares e tridimensionais são analisados neste trabalho. Para tanto, são obtidas as expressões das componentes dos campos e as equações características dos modos de interesse em estruturas planares por meio da técnica de matriz de transferência (TMT). A análise de propagação de onda em guias planares com materiais magnetoópticos é feita por meio de simulação numérica empregando o método de propagação de feixe (BPM) baseado em diferenças finitas (FD) e o esquema de Crank-Nicholson (CN) na discretização da solução da equação de onda. A condição de fronteira transparente (TBC) é incorporada ao algoritmo FD-BPM com a finalidade de se evitar reflexões de ondas eletromagnéticas para dentro da janela computacional. O método do índice efetivo é empregado na análise de guias de onda tridimensionais do tipo rib. / Optical communication networks have allowed a continuous increase of broadband services offer. The all-optical communication networks are becoming the most ambitious technological goal. Great efforts have been concentrated on the materiaIs and devices development and improvement to make it possible. Nonreciprocal devices, such as isolators and circulators constitute an important class of optical devices. Isolators are used in optical systems to avoid reflection of light in lasers and amplifiers. Circulators are used in signal derivation schemes that use wavelength division multiplexing (WDM). The operation of these devices is based on the properties of magnetooptic materiaIs. The purposes of this dissertation are to present the main features of the magnetooptic materiaIs as well as to analyze the eletromagnetic wave propagation in magnetooptic waveguides, exploring nonreciprocal features of TM modes. Planar and three-dimensional waveguides are analysed in this present study. Therefore expressions of electromagnetic field components and characteristic equations of the modes of interest in planar structures are obtained by using transfer matrix technique (TMT). The wave propagation analysis in planar magnetooptic waveguides is realized by using the finite-difference beam propagation method (FD-BPM) and Crank-Nicholson scheme (CN) applied to wave equation solution discretization. In order to avoid electromagnetic wave reflection into computational window, the transparent boundary condition (TBC) is incorporated to the FD-BPM formalism. The effective index method (EIM) is used in the analysis of three-dimensional rib magnetooptic waveguides.

Beam propagation method

Diferenças finitas

Dispositivos não-recíprocos

Effective index method

Finite-difference

Magnetooptic materials

Materiais magnetoópticos

Método de propagação de feixe

Método do índice efetivo

Nonreciprocal devices

Optical communications systems

Sistemas de comunicações ópticas

Técnica de matriz de transferência

Transfer matrix technique

Análise de dispositivos com materiais magnetoópticos para aplicações em sistemas de comunicações ópticas / not available

Evandro Assis Costa Gonçalves

21 September 2001

As redes ópticas de comunicação têm possibilitado, cada vez mais, o oferecimento de serviços do tipo faixa larga. A rede de comunicação totalmente óptica está se tornando a meta tecnológica mais ambiciosa. Grandes esforços têm sido concentrados no desenvolvimento e aperfeiçoamento de materiais e dispositivos não-recíprocos, como isoladores e circuladores constituem uma importante classe de dispositivos ópticos. Os isoladores são utilizados em sistemas ópticos para prevenir a reflexão de luz em lasers e amplificadores. Os circuladores são empregados em esquemas de derivação de sinais que utilizam multiplexação em comprimento de onda (WDM). O funcionamento destes dispositivos é baseado nas propriedades de materiais magnetoópticos. As metas desta dissertação são apresentar as principais características dos materiais magnetoópticos, explorando as características não-recíprocas dos modos TM. Guias planares e tridimensionais são analisados neste trabalho. Para tanto, são obtidas as expressões das componentes dos campos e as equações características dos modos de interesse em estruturas planares por meio da técnica de matriz de transferência (TMT). A análise de propagação de onda em guias planares com materiais magnetoópticos é feita por meio de simulação numérica empregando o método de propagação de feixe (BPM) baseado em diferenças finitas (FD) e o esquema de Crank-Nicholson (CN) na discretização da solução da equação de onda. A condição de fronteira transparente (TBC) é incorporada ao algoritmo FD-BPM com a finalidade de se evitar reflexões de ondas eletromagnéticas para dentro da janela computacional. O método do índice efetivo é empregado na análise de guias de onda tridimensionais do tipo rib. / Optical communication networks have allowed a continuous increase of broadband services offer. The all-optical communication networks are becoming the most ambitious technological goal. Great efforts have been concentrated on the materiaIs and devices development and improvement to make it possible. Nonreciprocal devices, such as isolators and circulators constitute an important class of optical devices. Isolators are used in optical systems to avoid reflection of light in lasers and amplifiers. Circulators are used in signal derivation schemes that use wavelength division multiplexing (WDM). The operation of these devices is based on the properties of magnetooptic materiaIs. The purposes of this dissertation are to present the main features of the magnetooptic materiaIs as well as to analyze the eletromagnetic wave propagation in magnetooptic waveguides, exploring nonreciprocal features of TM modes. Planar and three-dimensional waveguides are analysed in this present study. Therefore expressions of electromagnetic field components and characteristic equations of the modes of interest in planar structures are obtained by using transfer matrix technique (TMT). The wave propagation analysis in planar magnetooptic waveguides is realized by using the finite-difference beam propagation method (FD-BPM) and Crank-Nicholson scheme (CN) applied to wave equation solution discretization. In order to avoid electromagnetic wave reflection into computational window, the transparent boundary condition (TBC) is incorporated to the FD-BPM formalism. The effective index method (EIM) is used in the analysis of three-dimensional rib magnetooptic waveguides.

Diferenças finitas

Dispositivos não-recíprocos

Materiais magnetoópticos

Método de propagação de feixe

Método do índice efetivo

Sistemas de comunicações ópticas

Técnica de matriz de transferência

Beam propagation method

Effective index method

Finite-difference

Magnetooptic materials

Nonreciprocal devices

Optical communications systems

Transfer matrix technique