Design of Power-Scalable Gallium Nitride Class E Power Amplifiers

Connor, Mark Anthony

26 August 2014

No description available.

Electrical Engineering

gallium nitride

GaN

HEMT

power amplifier

class E

transistor

switch

reconfigurable

MMIC

power scaling

impedance matching

load-pull

RF

microwave

integrated circuit

Parametric Study via Numerical Simulations of Natural Convection in Laterally Heated Cylindrical Enclosures: Investigating Characteristic Length

Hirt, David M.

11 June 2018

No description available.

Mechanical Engineering

natural convection

gallium nitride crystals

lateral heating

cylindrical reactor

turbulent

laminar

boundary layer

characteristic length

simulations

transient

steady state

crystal growth

aspect ratio

Growth and Scanning Tunneling Microscopy Studies of Magnetic Films on Semiconductors and Development of Molecular Beam Epitaxy/Pulsed Laser Deposition and Cryogenic Spin-Polarized Scanning Tunneling Microscopy System

Lin, Wenzhi

26 July 2011

No description available.

Condensed Matter Physics

Materials Science

Physics

scanning tunneling microscopy

molecular beam epitaxy

gallium nitride

MBE/STM system development

ultra-high vacuum system development

Investigation of AlGaN films and nickel/AlGaN Schottky diodes using depth-dependent cathodoluminescence spectroscopy and secondary ion mass spectrometry

Bradley, Shawn Todd

04 March 2004

No description available.

GaN

AlN

AlGaN

gallium nitride

nitride

LEEN

cathodoluminescence

CL

IPE

internal photoemission spectroscopy

secondary ion mass spectrometry

SIMS

Schottky

doping

HFET

HEMT

UHV

Development of MOCVD GaN Homoepitaxy for Vertical Power Electronic Device Applications

Zhang, Yuxuan

02 September 2022

No description available.

Electrical Engineering

Materials Science

gallium nitride

vertical power devices

metalorganic chemical vapor deposition

laser-assisted MOCVD

carbon impurity

iron impurity

fast growth rate

defects

thermodynamic modelling

optical characteristics

High-Efficiency and High-Frequency Resonant Converter Based Single-Stage Soft-Switching Isolated Inverter Design and Optimization with Gallium-Nitride (GaN)

Wen, Hao

30 September 2021

Isolated inverter can provide galvanic isolation which is necessary for some applications with safety regulations. Traditionally, a two-stage configuration is widely applied with isolated dc-dc stage and a sinusoidal pulse-width-modulated (SPWM) dc-ac stage. However, this two-stage configuration suffers from more components count, more complex control and tend to have lower efficiency and lower power density. Meanwhile, a large dc bus capacitor is needed to attenuate the double line frequency from SPWM for two-stage configuration. Therefore, the single-stage approach including an isolated dc-rectified sine stage and a line frequency unfolder is preferable. Since the unfolder circuit is at line frequency being almost lossless, the isolated dc-rectified sine stage becomes critical. However, the relevant research for the single-stage isolated inverter is limited. People either utilize PWM based converter as dc-rectified sine stage with duty cycle adjustment or apply SRC or LLC resonant converter for better soft switching characteristics. For PWM based converter, hard switching restricts the overall inverter efficiency, while for SRC/LLC, enough wide voltage gain range and full range ZVS are the major issues. This dissertation aims to provide solutions for a high-efficiency, high-frequency resonant converter based single-stage soft-switching isolated inverter design. The LLC and LCLCL resonant converters are applied as the isolated dc-rectified sine stage with variable frequency modulation (VFM). Therefore, the rectified sine wave generation consists of many dc-dc conversion with different switching frequencies and an efficient dc-rectified sine stage design needs each dc-dc conversion to be with high efficiency. This dissertation will first propose the optimization methods for LLC converter dc-dc conversion. ZVS models are derived to ensure fully ZVS performance for primary side GaN devices. As a large part in loss breakdown, the optimization for transformer is essential. The LLC converter can achieve above 99% efficiency with proposed optimization approach. Moreover, the channel turn-off energy model is presented for a more accurate loss analysis. With all the design and optimization considerations, a MHz LLC converter based isolated inverter is designed and a hybrid modulation method is proposed, which includes full bridge (FB) VFM for output high line region and half bridge (HB) VFM for output low line region. By changing from FB to HB, the output voltage gain is reduced to half to have a wider voltage gain range. However, the total harmonic distortion (THD) of output voltage at light load will be impacted since the voltage gain will be higher with lighter load at the maximum switching frequency. A MHz LCLCL converter based isolated inverter is proposed for a better output voltage THD at light load conditions. The paralleled LC inside the LCLCL resonant tank can naturally create a zero voltage gain point at their resonant frequency, which shows superior performance for rectified sine wave generation. Besides the better THD performance, the LCLCL converter based isolated inverter also features for easier control, better ZVS performance and narrower switching frequency range. Meanwhile, the LCLCL based inverter topology has bi-directional power flow capability as well. With variable frequency modulation for ac-dc, this topology is still a single-stage solution compared to the traditional two-stage solution including PFC + LLC configuration. / Doctor of Philosophy / Inverters can convert dc voltage to ac voltage and typically people use two-stage approach with isolated dc-dc stage and dc-ac stage. However, this two-stage configuration suffers from more components count, more complex control and tend to have lower efficiency and lower power density. Therefore, the single-stage solution with dc-rectified sine wave stage and a line frequency unfolder becomes appealing. The unfolder circuit is to unfold the rectifier sine wave to an ac sine wave at the output. Since the unfolder is at line frequency and can be considered lossless, the key design is for the dc-rectified sine stage. The resonant converter featured for soft switching seems to be a good candidate. However, the inverter needs soft switching for the whole range and an enough wide voltage gain, which makes the design difficult, especially the target is high efficiency for the overall inverter. This dissertation aims to provide solutions for a high-efficiency, high-frequency resonant converter based single-stage soft-switching isolated inverter design. The LLC and LCLCL resonant converters are applied as the isolated dc-rectified sine stage with variable frequency modulation (VFM). Therefore, the rectified sine wave generation consists of many dc-dc conversion with different switching frequencies and an efficient dc-rectified sine stage design needs each dc-dc conversion to be with high efficiency. The design considerations and optimization methods for the LLC dc-dc conversion are firstly investigated. Based on these approaches, a MHz LLC converter based isolated inverter is designed with proposed hybrid modulation method. To further improve the light load performance, a MHz LCLCL converter based isolated inverter topology is proposed. The paralleled LC inside the LCLCL resonant tank can naturally create a zero voltage gain point which shows superior characteristics for rectified sine wave generation. Moreover, the LCLCL resonant converter based topology has bi-directional capability as well so it can work well for ac voltage to dc voltage conversion.

Single-stage isolated inverter

LLC resonant converter

multi-element resonant converter

zero-voltage-switching (ZVS)

variable frequency modulation

Gallium Nitride (GaN)

Microstructural characterisation of novel nitride nanostructures using electron microscopy

Severs, John

January 2014

Novel semiconductor nanostructures possess a range of notable properties that have the potential to be harnessed in the next generation of optical devices. Electron microscopy is uniquely suited to characterising the complex microstructure, the results of which may be related to the growth conditions and optical properties. This thesis investigates three such novel materials: (1) GaN/InGaN core/shell nanowires, (2) n-GaN/InGaN/p-GaN core/multi-shell microrods and (3) Zn₃N₂ nanoparticles, all of which were grown at Sharp Laboratories of Europe. GaN nanowires were grown by a Ni-catalysed VLS process and were characterised by various techniques before and after InGaN shells were deposited by MOCVD. The majority of the core wires were found to have the expected wurtzite structure and completely defect free – reflected in the strong strain-free photoluminescence peak –with a- and m- axis orientations identified with shadow imaging. A small component, <5%, were found to have the cubic zinc-blende phase and a high density of planar faults running the length of the wires. The deposited shells were highly polycrystalline, partially attributed to a layer of silicon at the core shell interface identified through FIB lift-out of cross section samples, and accordingly the PL was very broad likely due to recombination at defects and grain boundaries. A high throughput method of identifying the core size indirectly via the catalyst particle EDX signal is described which may be used to link the shell microstructure to core size in further studies. An n-GaN/InGaN/p-GaN shell structure was deposited by MOCVD on the side walls of microrods etched from c-axis GaN film on sapphire, which offers the possibility of achieving non-polar junctions without the issues due to non-uniformity found in nanowires. Threading dislocations within the core related to the initial growth on sapphire were shown to be confined to this region, therefore avoiding any harmful effect on the junction microstructure. The shell defect density showed a surprising relationship to core size with the smaller diameter rods having a high density of unusual 'flag' defects in the junction region whereas the larger diameter sample shells appeared largely defect free, suggesting the geometry of the etched core has an impact on the strain in the shell layers. The structure of unusual 'flag' defects in the m-plane junctions was characterised via diffraction contrast TEM, weak beam and atomic resolution ADF STEM and were shown to consist of a basal plane stacking faults meeting a perfect or partial dislocation loop on a pyramidal plane, the latter likely gliding in to resolve residual strain due to the fault formed during growth. Zn₃N₂ has the required bandgap energy to be utilised as a phosphor with the additional advantage over conventional materials of its constituent elements not being toxic or scarce. The first successful synthesis of Zn₃N₂ nanoparticles appropriate to this application was confirmed via SAD, EDX and HRTEM, with software developed to fit experimental polycrystalline diffraction patterns to simulated components suggesting a maximum Zn₃N₂ composition of ~30%. There was an apparent decrease in crystallinity with decreasing particle size evidenced in radial distribution function studies with the smallest particles appearing completely amorphous in 80kV HRTEM images. A rapid change in the particles under the electron beam was observed, characterised by growth of large grains of Zn₃N₂ and ZnO which increased with increasing acceleration voltage suggesting knock-on effects driving the change. PL data was consistent with the bandgap of Zn₃N₂ blue shifted from 1.1eV to around 1.8eV, confirming the potential of the material for application as a phosphor.

621.3815

Convertisseurs continu-continu non isolés à haut rapport de conversion pour piles à combustible et électrolyseurs : apport des composants GaN / Non-isolated high voltage ratio DC-DC converter for fuel cell and electrolyzer : GaN transistors

Videau, Nicolas

05 May 2014

Face aux enjeux énergétiques d’aujourd’hui et de demain, le développement des énergies renouvelables semble inéluctable. Cependant, la production électrique de sources renouvelables prometteuses comme le photovoltaïque ou l’éolien est intermittente et difficilement prévisible du fait de la dépendance de ces sources aux conditions météorologiques. Afin de s’affranchir du caractère discontinu de la production d’électricité et de l’inadéquation de la production avec la consommation, un moyen de stockage de l’énergie électrique est nécessaire. Dans ce contexte, la batterie hydrogène est une des solutions envisagées. Lors de périodes de surproduction d’énergie renouvelable, un électrolyseur produit de l’hydrogène par électrolyse de l’eau. Lorsque cela est nécessaire, une pile à combustible fournit de l’électricité à partir du gaz stocké. Couplé avec des sources d’énergie renouvelable, la batterie hydrogène produit de l’énergie électrique non carbonée, c’est-à-dire non émettrice de gaz à effet de serre. L’intérêt majeur de cette technologie est le découplage entre l’énergie et la puissance du système. Tant que la pile à combustible est alimentée en gaz, elle fournit de l’électricité, l’énergie dépend des réservoirs de gaz. La puissance, quant à elle, dépend des caractéristiques des composants électrochimiques et du dimensionnement des chaînes de conversions de puissance. Les chaînes de conversion de puissance relient les composants électrochimiques au réseau électrique. Dans le cas de la chaîne de conversion sans transformateur qui est ici envisagée, la présence d’un convertisseur DC-DC à haut rendement à fort ratio de conversion est rendue nécessaire de par la caractéristique basse tension fort courant des composants électrochimiques. Avec pour but principal l’optimisation du rendement, deux axes de recherche sont développés. Le premier axe développe un convertisseur multicellulaire innovant à haut rendement à fort ratio de conversion. Les résultats expérimentaux du convertisseur appelé « miroir » obtenus dans deux expérimentations ont démontré la supériorité de cette topologie en terme d’efficacité énergétique par rapport aux convertisseurs conventionnels. Le deuxième axe porte sur de nouveaux composants de puissance en nitrure de gallium (GaN) annoncés comme une rupture technologique. Un convertisseur buck multi-phases illustre les défis technologiques et scientifiques de cette technologie et montre le fort potentiel de ces composants. / Development of renewable energy seems inevitable to face the energy challenge of today and tomorrow. However, the power generation of promising renewable sources such as solar or wind power is intermittent and unpredictable due to the dependence of the these sources to the weather. In order to overcome the discontinuous nature of the electricity production and the mismatch between production and consumption, electrical energy storage is needed. In this context, hydrogen battery is one of the solutions. During periods of overproduction of renewable energy, an electrolyzer produces hydrogen gas by the electrolysis of water. When necessary, a fuel cell provides electricity from the stored gas. Coupled with renewable energy sources, the hydrogen battery produces carbon-free electricity, i.e. without any greenhouse gas emission. The major advantage of this technology is the decoupling between energy and power system. As long as the fuel cell is supplied with gas, it supplies electricity. Like so, the energy depends on the gas tanks and the system power depends on the characteristics of electrochemical components and the design of the power conversion chain. Power converters connect electrochemical components to the grid. In the case of the transformerless conversion system introduce here, a high efficiency high voltage gain DC-DC converter is required given the high-current low-voltage characteristic of electrochemical components. Since the main goal is to optimize the efficiency, two research approaches are developed. The first develops an innovating multicell converter with high efficiency at high voltage conversion ratio. The experimental results of the “mirror” converter obtained in two experiments have demonstrated the superiority of this topology in terms of energy efficiency compared to conventional converters. The second line of research focuses on new gallium nitride (GaN) transistors heralded as a disruptive technology. A multiphase buck converter illustrates the technological and scientific challenges of this technology and shows the potential of these transistors.

Convertisseurs DC-DC multicellulaires

Convertisseurs Miroir

Hydrogen battery

Fuel cell and electrolyzer association

Multicell DC-DC converters

Mirror converters

Gallium nitride (GaN) power transistors

Quantum Chemical Feasibility Study of Methylamines as Nitrogen Precursors in Chemical Vapor Deposition

Rönnby, Karl

January 2015

The possibility of using methylamines instead of ammonia as a nitrogen precursor for the CVD of nitrides is studied using quantum chemical computations of reaction energies: reaction electronic energy (Δ𝑟𝐸𝑒𝑙𝑒𝑐) reaction enthalpy (Δ𝑟𝐻) and reaction free energy (Δ𝑟𝐺). The reaction energies were calculated for three types of reactions: Uni- and bimolecular decomposition to more reactive nitrogen species, adduct forming with trimethylgallium (TMG) and trimethylaluminum (TMA) followed by a release of methane or ethane and surface adsorption to gallium nitride for both the unreacted ammonia or methylamines or the decomposition products. The calculations for the reaction entropy and free energy were made at both STP and CVD conditions (300°C-1300°C and 50 mbar). The ab inito Gaussian 4 (G4) theory were used for the calculations of the decomposition and adduct reactions while the surface adsorptions were calculated using the Density Functional Theory method B3LYP. From the reactions energies it can be concluded that the decomposition was facilitated by the increasing number of methyl groups on the nitrogen. The adducts with mono- and dimethylamine were more favorable than ammonia and trimethylamine. 𝑁𝐻2 was found to be most readily to adsorb to 𝐺𝑎𝑁 while the undecomposed ammonia and methylamines was not willingly to adsorb.

Quantum Chemistry

Computational Chemistry

Density Functional Theory (DFT)

B3LYP

Gaussian 4 (G4)

Chemical Vapor Deposition (CVD)

Gallium Nitride (GaN)

Aluminum Nitride (AlN)

Ammonia (NH3)

Methylamine (NH2CH3)

Dimethylamine (NH(CH3)2)

Trimethylamine (NH(CH3)3)

Trimethylaluminum (TMA)

Trimethylgallium (TMG)

Decomposition

Adsorption

Caractérisations et modélisations physiques de contacts entre phases métalliques et Nitrure de Gallium semi-conducteur / Characterization and physical modelling of contacts between metallic phases and Gallium Nitride

Thierry-Jebali, Nicolas

14 December 2011

Les composés III-N, et le Nitrure de Gallium (GaN) en particulier, sont devenus des matériaux semi conducteurs importants pour l’ensemble de l’humanité. Depuis la fin des années 1990, ils ont permis le développement de composants électroluminescents fiables, diodes LED et diodes laser, qui constituent une solution de remplacement à rendement énergétique amélioré par rapport aux composants à incandescence. Il est possible qu’ils jouent aussi un rôle dans les nouvelles générations de composants pour l’électronique de puissance. Lors du développement des composants, des recherches expérimentales permettent de trouver assez rapidement des solutions pour réaliser les briques technologiques indispensables, mais le temps manque pour comprendre les mécanismes physiques mis en jeu. Nos travaux ont eu pour objectif d’approfondir la compréhension de l’influence de la structure physico-chimique sur les propriétés électriques des contacts ohmiques et Schottky sur GaN de type N. / Group III nitride semiconductor materials (III-N), and especially gallium nitride (GaN), are now key materials for the whole human kind. Since years 1990, reliable and energy-efficient light emitting devices have been developed based on III-N compounds providing higher efficiency replacement solutions to incandescent bulbs. The same III-N materials may also provide higher performance device solutions for power electronics, allowing multi-functional on-chip integration. During the industrial development of devices, experimental work is focused on finding rapidly good enough solutions for each technology brick, and on the eventual integration of the bricks into a complete device processing flow. Very often, little time and effort can be devoted to the understanding of the underlying physical and chemical processes. The aim of this work has been to study the influence of the physical and chemical material structures on the electrical properties of metal - GaN Ohmic and Schottky contacts.

Nitrure de Gallium

Redresseur Schottky

Contact Métal - Semiconducteur

Caractérisations Physico-chimiques

Caractérisation électriques

Modélisations physiques

Gallium Nitride

Schottky rectifier

Metal - Semiconductor contact

Physical characterizations

Chemical characterizations

Electrical characterizations

Physical modeling

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