Global ETD Search

581	Croissance et caractérisation de nanofils/microfils de GaN Coulon, Pierre-Marie 20 May 2014 (has links) (PDF) Ce travail de thèse ce focalise sur la croissance et la caractérisation de Nanofils (NFs) et de Microfils (µFs) de GaN. L'élaboration de telles structures est obtenue par épitaxie en phase vapeur d'organométalliques à partir de deux stratégies de croissances: l'une dite auto-organisée, réalisée sur substrat saphir, l'autre appelée sélective ou localisée, obtenue sur template GaN de polarité Ga. Quelque soit la stratégie employée, nous montrons que la croissance de structures verticales suivant l'axe c requièrent l'utilisation d'un flux de NH3 et d'un rapport V/III faible, lorsque nous les comparons avec les valeurs utilisées pour la réalisation de couches planaires de GaN. Les paramètres et les étapes de croissances ayant une influence sur le rapport d'aspect (hauteur/diamètre) sont étudiées et mises en évidence pour chacune des stratégies employées. Par ailleurs, les mécanismes de croissance ainsi que les propriétés structurales et optiques de ces objets sont caractérisés par MEB, MET, CL et µPL. En particulier, les expériences réalisées sur les µFs auto-organisés permettent d'observer et d'expliquer l'origine de la double polarité, de mettre en lueur la différence d'incorporation de dopants/d'impuretés entre les domaines Ga et N, d'identifier la présence de deux sections de propriétés électriques et optiques différentes, et de révéler la présence de deux types de résonances optiques: des Modes de galerie et des Modes de Fabry-Perot. D'autres part, nous étudions la courbure des dislocations vers les surfaces libres des NFs localisés et µFs auto-organisés, et pointons la présence de fautes d'empilement basales dans des régions de faibles dimensions. GaN Nanofils Auto-organisée Localisée Caractérisation Polarité Dopage Si Résonances optiques Défauts structuraux
582	Analysis of thermal conductivity models with an extension to complex crystalline materials Greenstein, Abraham 08 July 2008 (has links) The calculation of the thermal conductivity of condensed matter has posed a significant challenge to engineers and scientists for almost a century. Thermal conductivity models have been successfully applied to many materials however many challenges still remain. One serious challenge is the inability of current thermal conductivity models to calculate the thermal conductivity of highly complex materials. Another challenge is managing error introduced by using an effective interatomic potential, for many materials this problem is exacerbated because their effective potentials have not been extensively used or characterized. Recent interest in nanostructures has initiated a new set of challenges and unanswered questions. This work addresses different aspects of the aforementioned challenges by using zeolite MFI and gallium nitride as case studies. Thermal properties Zeolites GaN Nanotechnology Heat transfer Thermal conductivity Condensed matter Zeolites Gallium nitride Phonons Lattice dynamics Nanowires Zeolites Thermal properties Gallium nitride Thermal properties
583	Modelling, characterisation and application of GaN switching devices Murillo Carrasco, Luis January 2016 (has links) The recent application of semiconductor materials, such as GaN, to power electronics has led to the development of a new generation of devices, which promise lower losses, higher operating frequencies and reductions in equipment size. The aim of this research is to study the capabilities of emerging GaN power devices, to understand their advantages, drawbacks, the challenges of their implementation and their potential impact on the performance of power converters. The thesis starts by presenting the development of a simple model for the switching transients of a GaN cascode device under inductive load conditions. The model enables accurate predictions to be made of the switching losses and provides an understanding of the switching process and associated energy flows within the device. The model predictions are validated through experimental measurements. The model reveals the suitability of the cascode device to soft-switching converter topologies. Two GaN cascode transistors are characterised through experimental measurement of their switching parameters (switching speed and switching loss). The study confirms the limited effect of the driver voltage and gate resistance on the turn-off switching process of a cascode device. The performance of the GaN cascode devices is compared against state-of-the-art super junction Si transistors. The results confirm the feasibility of applying the GaN cascode devices in half and full-bridge circuits. Finally, GaN cascode transistors are used to implement a 270V - 28V, 1.5kW, 1 MHz phase-shifted full-bridge isolated converter demonstrating the use of the devices in soft-switching converters. Compared with a 100 kHz silicon counterpart, the magnetic component weight is reduced by 69% whilst achieving a similar efficiency of 91%.
584	A Framework for Generative Product Design Powered by Deep Learning and Artificial Intelligence : Applied on Everyday Products Nilsson, Alexander, Thönners, Martin January 2018 (has links) In this master’s thesis we explore the idea of using artificial intelligence in the product design process and seek to develop a conceptual framework for how it can be incorporated to make user customized products more accessible and affordable for everyone. We show how generative deep learning models such as Variational Auto Encoders and Generative Adversarial Networks can be implemented to generate design variations of windows and clarify the general implementation process along with insights from recent research in the field. The proposed framework consists of three parts: (1) A morphological matrix connecting several identified possibilities of implementation to specific parts of the product design process. (2) A general step-by-step process on how to incorporate generative deep learning. (3) A description of common challenges, strategies andsolutions related to the implementation process. Together with the framework we also provide a system for automatic gathering and cleaning of image data as well as a dataset containing 4564 images of windows in a front view perspective. Generative Design Deep Learning Machine Learning Artificial Intelligence Variational Auto Encoder Generative Adversarial Network VAE GAN Design Variations Windows Mullions Framework Windows Dataset Computer Engineering Datorteknik
585	Difúzní rozptyl rentgenového záření na GaN epitaxních vrstvách / Diffuse x-ray scattering from GaN epitaxial layers Barchuk, Mykhailo January 2012 (has links) Real structure of heteroepitaxial GaN and AlGaN layers is studied by diffuse x-ray scattering. A new developed method based on Monte Carlo simulation enabling to determine densities of threading dislocations in c-plane GaN and stacking faults in a-plane GaN is presented. The results of Monte Carlo simulations are compared with ones obtained by use of other conventional techniques. The advantages and limitations of the new method are discussed in detail. The methods accuracy is estimated as about 15%. We have shown that our method is a reliable tool for threading dislocations and stacking faults densities determination.
586	Síntese por feixe de íons de GaN-layer sobre GaAs Coelho Júnior, Horácio January 2018 (has links) O Nitreto de Gálio (GaN) é um semicondutor de gap direto, motivo de numerosas pesquisas científicas, principalmente devido a sua importância na fabricação de dispositivos de alta potência e optoeletrônicas. Ligas de GaN como InGaN e AlGaN, por exemplo, possibilitam a fabricação de LEDs e LASERs azuis. Neste nosso estudo selecionamos o Arseneto de Gálio (GaAs) como um substrato viável para síntese de GaN mediante a permuta de Arsênio (As) por Nitrogênio (N) fundamentada em três passos: a) incorporação de N por implantação iônica em GaAs (à 350, 450 ou 550 ºC) em elevadas fluências (1, 2, 3 ou 4 × 1017 N/cm2); b) maior estabilidade das ligações Ga-N frente às de Ga-As; e c) expurgo de As da região contendo N implantado mediante recozimentos (à 550, 650, 750, 850 ou 1000 ºC) sob fluxo de N2. Uma capa de ~ 125 nm de Nitreto de Silício (Si3N4) foi depositada por sputtering sobre o GaAs previamente a implantação à quente: camada de sacrifício que pode ser removida após a síntese. Análises por Microscopia Eletrônica de Transmissão (TEM) e Espectroscopia de Raios- X por Dispersão em Energia (EDS) demonstraram que, no estado como-implantado da fluência de 3 × 1017 N/cm2, formam-se bolhas de N para ambos os lados da interface Si3N4/GaAs e a região implantada do GaAs amorfiza. Após um recozimento à 850 ºC/5 min, observou-se uma elevada degradação da camada de Si3N4, fragilizada pela formação das bolhas de N. Formou-se uma camada contínua de GaN (GaN-layer) de ~ 70 nm na sua fase hexagonal, sustentada por “pilares” no substrato GaAs, entre os quais existem extensos vazios. Medidas TEM em alta resolução (HRTEM) e por Difração de Elétrons de Área Selecionada (SAED) revelaram que a GaN-layer apresenta forte tendência à epitaxia com o substrato GaAs (relações de epitaxia são aqui apresentadas), e regiões estruturalmente espelhadas (i.e., twins). SAED sobre os pilares evidenciaram uma fase transicional cúbica, com um parâmetro de rede substancialmente menor (0,42 ± 0,01) nm que o reportado na literatura (0,45 nm). Estudos por Espectrometria de Retroespalhamento de Rutherford e Canalização (RBS/C) mostraram que a GaN-layer é rica em N (Ga1,00N1,90, para 3 × 1017 N/cm2) e apresenta canalização (para implantações de 2 e 3 × 1017 N/cm2), confirmando o caráter monocristalino identificado por TEM. Medidas de Fotoluminescência (PL) confirmam emissão na região do gap de banda do α-GaN (~ 3,4 eV), bem como bandas associadas a defeitos estruturais do material. Também foi investigado o efeito de campos de tensão provenientes de bolhas de Hélio (He) mediante a realização da síntese a partir de substrato GaAs pré-implantado com He. Neste caso, as bolhas, que se formam no GaAs durante a implantação de N à quente e extinguem-se após recozimentos, limitam a difusão de N para o interior do substrato, conduzindo a formação de uma GaN-layer mais espessa (~ 120 nm) e com bem mais N (Ga1,00N2,80). Como consequência, a GaNlayer apresentou um caráter mais policristalino. / The Gallium Nitride (GaN) is a direct gap semiconductor, is issue of numerous scientific research, mainly due to its importance in the manufacture of high power devices and optoelectronic devices. GaN alloys, as InGaN and AlGaN, for example, enable the production of LEDs and blue LASERs. In this study, we have selected Gallium Arsenide (GaAs) as a suitable substrate for GaN synthesis through Arsenic (As) replacement by Nitrogen (N), based on three steps: a) incorporation of N by ion implantation into GaAs (at 350, 450 or 550 ºC) at high fluences (1, 2, 3 or 4 × 1017 N/cm2); b) higher stability of the Ga-N bonds compared to the Ga-As ones; and c) purge of As from the region containing implanted N by annealing (at 550, 650, 750, 850 or 1000 ºC) under N2 flow. A 125-nm cap-layer of Silicon Nitride (Si3N4) was deposited by sputtering on GaAs prior to the hot implantation: it is a sacrifice layer which can be removed after the synthesis. Transmission Electron Microscopy (TEM) and Energy Dispersive X-ray Spectroscopy (EDS) analyzes demonstrated that, on the as-implanted state of the fluence of 3 × 1017 N/cm2, N bubbles are formed on both sides of the Si3N4/GaAs interface and the implanted region of GaAs amorphizes. After annealing at 850 °C/5min, a high degradation of the Si3N4 layer was observed, weakened by the formation of N bubbles. A continuous layer of GaN (GaN-layer) of ~ 70 nm was formed in its hexagonal phase, supported by “pillars” on the GaAs substrate, with extensive voids in between them. High-Resolution TEM (HRTEM) and Selected Area Electron Diffraction (SAED) measurements revealed that the GaN-layer exhibits a strong tendency to epitaxy with the GaAs substrate (epitaxial relationships are here presented), and structurally mirrored regions (i.e., twins). SAED on the pillars showed a transitional cubic phase, with a lattice parameter substantially smaller (0.42 ± 0.01) nm than the one reported in the literature (0.45 nm). Rutherford Backscattering Spectrometry studies and Channeling (RBS/C) showed that the GaN-layer is rich in N (Ga1.00N1.90, for 3 × 1017 N/cm2) and presents channeling (for implantations of 2 and 3 × 1017 N/cm2), corroborating the monocrystalline nature identified by TEM. Photoluminescence (PL) measurements confirm emission in the band gap region of a- GaN (~ 3.4 eV), as well as bands associated to structural defects in the material. It was also investigated the effect of strain fields from Helium (He) bubbles through synthesis starting up from He pre-implanted GaAs substrate. In this case, the bubbles, which are formed in the GaAs during the hot N-implantation and are annihilated after annealing, limit the N diffusion into the substrate, leading to the formation of a thicker GaN-layer (~ 120 nm) and with much more N (Ga1.00N2.80). As a result, the GaN-layer presented an aspect more polycrystalline. Feixes de íons Arseneto de galio Microscopia eletrônica de transmissão GaN-layer synthesis PL RBS/C TEM N ion implantation into GaAs
587	Síntese por feixe de íons de GaN-layer sobre GaAs Coelho Júnior, Horácio January 2018 (has links) O Nitreto de Gálio (GaN) é um semicondutor de gap direto, motivo de numerosas pesquisas científicas, principalmente devido a sua importância na fabricação de dispositivos de alta potência e optoeletrônicas. Ligas de GaN como InGaN e AlGaN, por exemplo, possibilitam a fabricação de LEDs e LASERs azuis. Neste nosso estudo selecionamos o Arseneto de Gálio (GaAs) como um substrato viável para síntese de GaN mediante a permuta de Arsênio (As) por Nitrogênio (N) fundamentada em três passos: a) incorporação de N por implantação iônica em GaAs (à 350, 450 ou 550 ºC) em elevadas fluências (1, 2, 3 ou 4 × 1017 N/cm2); b) maior estabilidade das ligações Ga-N frente às de Ga-As; e c) expurgo de As da região contendo N implantado mediante recozimentos (à 550, 650, 750, 850 ou 1000 ºC) sob fluxo de N2. Uma capa de ~ 125 nm de Nitreto de Silício (Si3N4) foi depositada por sputtering sobre o GaAs previamente a implantação à quente: camada de sacrifício que pode ser removida após a síntese. Análises por Microscopia Eletrônica de Transmissão (TEM) e Espectroscopia de Raios- X por Dispersão em Energia (EDS) demonstraram que, no estado como-implantado da fluência de 3 × 1017 N/cm2, formam-se bolhas de N para ambos os lados da interface Si3N4/GaAs e a região implantada do GaAs amorfiza. Após um recozimento à 850 ºC/5 min, observou-se uma elevada degradação da camada de Si3N4, fragilizada pela formação das bolhas de N. Formou-se uma camada contínua de GaN (GaN-layer) de ~ 70 nm na sua fase hexagonal, sustentada por “pilares” no substrato GaAs, entre os quais existem extensos vazios. Medidas TEM em alta resolução (HRTEM) e por Difração de Elétrons de Área Selecionada (SAED) revelaram que a GaN-layer apresenta forte tendência à epitaxia com o substrato GaAs (relações de epitaxia são aqui apresentadas), e regiões estruturalmente espelhadas (i.e., twins). SAED sobre os pilares evidenciaram uma fase transicional cúbica, com um parâmetro de rede substancialmente menor (0,42 ± 0,01) nm que o reportado na literatura (0,45 nm). Estudos por Espectrometria de Retroespalhamento de Rutherford e Canalização (RBS/C) mostraram que a GaN-layer é rica em N (Ga1,00N1,90, para 3 × 1017 N/cm2) e apresenta canalização (para implantações de 2 e 3 × 1017 N/cm2), confirmando o caráter monocristalino identificado por TEM. Medidas de Fotoluminescência (PL) confirmam emissão na região do gap de banda do α-GaN (~ 3,4 eV), bem como bandas associadas a defeitos estruturais do material. Também foi investigado o efeito de campos de tensão provenientes de bolhas de Hélio (He) mediante a realização da síntese a partir de substrato GaAs pré-implantado com He. Neste caso, as bolhas, que se formam no GaAs durante a implantação de N à quente e extinguem-se após recozimentos, limitam a difusão de N para o interior do substrato, conduzindo a formação de uma GaN-layer mais espessa (~ 120 nm) e com bem mais N (Ga1,00N2,80). Como consequência, a GaNlayer apresentou um caráter mais policristalino. / The Gallium Nitride (GaN) is a direct gap semiconductor, is issue of numerous scientific research, mainly due to its importance in the manufacture of high power devices and optoelectronic devices. GaN alloys, as InGaN and AlGaN, for example, enable the production of LEDs and blue LASERs. In this study, we have selected Gallium Arsenide (GaAs) as a suitable substrate for GaN synthesis through Arsenic (As) replacement by Nitrogen (N), based on three steps: a) incorporation of N by ion implantation into GaAs (at 350, 450 or 550 ºC) at high fluences (1, 2, 3 or 4 × 1017 N/cm2); b) higher stability of the Ga-N bonds compared to the Ga-As ones; and c) purge of As from the region containing implanted N by annealing (at 550, 650, 750, 850 or 1000 ºC) under N2 flow. A 125-nm cap-layer of Silicon Nitride (Si3N4) was deposited by sputtering on GaAs prior to the hot implantation: it is a sacrifice layer which can be removed after the synthesis. Transmission Electron Microscopy (TEM) and Energy Dispersive X-ray Spectroscopy (EDS) analyzes demonstrated that, on the as-implanted state of the fluence of 3 × 1017 N/cm2, N bubbles are formed on both sides of the Si3N4/GaAs interface and the implanted region of GaAs amorphizes. After annealing at 850 °C/5min, a high degradation of the Si3N4 layer was observed, weakened by the formation of N bubbles. A continuous layer of GaN (GaN-layer) of ~ 70 nm was formed in its hexagonal phase, supported by “pillars” on the GaAs substrate, with extensive voids in between them. High-Resolution TEM (HRTEM) and Selected Area Electron Diffraction (SAED) measurements revealed that the GaN-layer exhibits a strong tendency to epitaxy with the GaAs substrate (epitaxial relationships are here presented), and structurally mirrored regions (i.e., twins). SAED on the pillars showed a transitional cubic phase, with a lattice parameter substantially smaller (0.42 ± 0.01) nm than the one reported in the literature (0.45 nm). Rutherford Backscattering Spectrometry studies and Channeling (RBS/C) showed that the GaN-layer is rich in N (Ga1.00N1.90, for 3 × 1017 N/cm2) and presents channeling (for implantations of 2 and 3 × 1017 N/cm2), corroborating the monocrystalline nature identified by TEM. Photoluminescence (PL) measurements confirm emission in the band gap region of a- GaN (~ 3.4 eV), as well as bands associated to structural defects in the material. It was also investigated the effect of strain fields from Helium (He) bubbles through synthesis starting up from He pre-implanted GaAs substrate. In this case, the bubbles, which are formed in the GaAs during the hot N-implantation and are annihilated after annealing, limit the N diffusion into the substrate, leading to the formation of a thicker GaN-layer (~ 120 nm) and with much more N (Ga1.00N2.80). As a result, the GaN-layer presented an aspect more polycrystalline. Feixes de íons Arseneto de galio Microscopia eletrônica de transmissão GaN-layer synthesis PL RBS/C TEM N ion implantation into GaAs
588	Efficient Dislocation Reduction Methods for Integrating Gallium Nitride HEMTs on Si Mohan, Nagaboopathy January 2014 (has links) (PDF) Gallium Nitride (GaN) and its alloys with InN and AlN, the III-nitrides, are of interest for a variety of high power-high frequency electronics and optoelectronics applications. However, unlike Si and GaAs technology that have been developed on native substrates, III-nitride devices have been developed on non-native substrates such as Si, sapphire and SiC. This is because bulk cheap native III-nitride substrates are unavailable. Among the known substrates, III-nitride technology development on Si is desirable because of its large substrate size and low cost. However, the large lattice and thermal expansion mismatch between the III-nitrides films and Si substrate leads to a high level of dislocations, 1010 cm-2, and tensile stress which results in cracking. For successful integration of crack free and low dislocation density GaN on Si various kinds of transition layer schemes are used that help to incorporate a compressive growth stress to neutralize the tensile thermal mismatch stresses and also to reduce dislocation densities to levels required by devices. These transition schemes, ranging from 400 nm to 7 m, involve the use of graded AlGaN layers, high/low temperature interlayers and superlattices. The aim of the research described in this thesis was a systematic comparison of the different transition layer schemes currently used with the objective of increasing the efficiency of integrating device quality, crack free, low dislocation density, <109 cm-2, GaN with Si. A metal organic chemical vapor deposition equipped with an in-situ stress monitor was used for growth. Transmission electron microscopy was used for quantitative measurement of dislocation density. The research shows, for the first time, that all transition layer optimization depends critically on the Si surface made available for growth of the first AlN layer. It needs to be optimally cleaned such that it is oxide free and smooth. A quantitative TEM comparison of various currently used transition layer schemes shows that while they have interesting mechanistic differences, they are not very different in their dislocation reduction efficiency. All of them yield a final dislocation density in a probe GaN layer of 1-3×109 cm-2. In contrast, a combination of Si doping and compressive growth stress has a synergistic effect on dislocation reduction. A simple 210 nm transition layer based on this understanding, the lowest reported yet, yields GaN layers that are crack free and have lower <1x109 cm-2 dislocation density, than those obtained by the aforementioned more complicated schemes. High electron mobility transistor characteristics performance on the probe GaN layers obtained on these transition layers supports the structural observations above. Gallium Nitrides Gallium Nitride Alloys Gallium Nitride Dislocation Reduction Gallium Nitride on Silicon High Electron Mobility Transistors Si Doping GaN Materials Science
589	Nanostructures And Thin Films Of III-V Nitride Semiconductors Sardar, Kripasindhu 10 1900 (has links) (PDF) No description available. Semiconductors Thin Films Nanostructures Nitrides Nitride Semiconductors Nanowires Nanocrystals Semiconductor Nanostructures AlN GaN InN Gallium Nitride Nanotubes Nitnde Thin Films GaMnN Films Nanotechnology
590	Effect of Process Parameters on the Growth of N-Polar GaN on Sapphire by MOCVD Yaddanapudi, G R Krishna January 2016 (has links) (PDF) Group III-Nitrides (GaN, InN & AlN) are considered one of the most important class of semiconducting materials after Si and GaAs. The excellent optical and electrical properties of these nitrides result in numerous applications in lighting, lasers, and high-power/high-frequency devices. Due to the lack of cheap bulk III- Nitride substrates, GaN based devices have been developed on foreign substrates like Si, sapphire and SiC. These technologies have been predominantly developed on the so called Ga-polarity epitaxial stacks with growth in the [0001] direction of GaN. It is this orientation that grows most easily on sapphire by metal organic chemical vapor deposition (MOCVD), the most common combination of substrate and deposition method used thus far. The opposite [000¯1] or N-polar orientation, very different in properties due to the lack of an inversion centre, offers several ad- vantages that could be exploited for better electronic and optoelectronic devices. However, its growth is more challenging and needs better understanding. The aim of the work reported in this dissertation was a systematic investigation of the relation between the various growth parameters which control polarity, surface roughness and mosaicity of GaN on non-miscut sapphire (0001) wafers for power electronics and lighting applications, with emphasis on the realization of N-polar epitaxial layers. GaN is grown on sapphire (0001) in a two-step process, which involves the deposition of a thin low temperature GaN nucleation layer (NL) on surface modified sapphire followed by the growth of high temperature device quality GaN epitaxial layer. The processing technique used is MOCVD. Various processing methods for synthesis of GaN layers are described with particular em- phasis on MOCVD method. The effect of ex situ cleaning followed by an in situ cleaning on the surface morphology of sapphire (0001) wafers is discussed. The characterization tools used in this dissertation for studying the chemical bond nature of nitrided sapphire surface and microstructural evolution (morphological and structural) of GaN layers are described in detail. The effect of nitridation temperature (TN) on structural transformation of non- miscut sapphire (0001) surface has been explored. The structural evolution of nitrided layers at different stages of their process like as grown stage and thermal annealing stage is investigated systematically. The chemical bond environment information of the nitrided layers have been examined by x-ray photoelectron spectroscopy (XPS). It is found that high temperature nitridation (TN ≥ 800oC) results in an Al-N tetrahedral bond environment on sapphire surface. In contrast, low temperature nitridation (TN = 530oC) results in a complex Al-O-N environment on sapphire surfaces. Microstructural evolution of low temperature GaN NLs has been studied at every stage of processing by scanning electron microscopy (SEM) and atomic force microscopy (AFM). Surface roughness evolution and island size distribution of NLs measured from AFM are discussed. It is found that NLs processed on sapphire wafers nitrided at (TN ≥ 800oC) showed strong wurtzite [0002] orientation with sub-nanometre surface roughness. In contrast, NLs processed at (TN = 530oC) showed zinc blende phase in the as grown stage with higher surface roughness, but acquired a greater degree of wurtzite [0002] orientation after thermal annealing prior to high temperature GaN growth. Polarity, surface quality and crystal quality of subsequently grown high temperature GaN epitaxial layers is described in relation to the structure of the trans- formed nitrided layers. Higher nitridation temperatures (TN ≥ 800oC) consistently yield N-polar GaN whereas lower nitridation temperatures (TN = 530oC) yield Ga-polar GaN. It is found that the relative O atom concentration levels in nitrided layers control the density of inversion domains in N-polar GaN. The effect of various growth parameters (NH3 flow rate, growth temperature, NL thickness) on surface morphology and mosaicity of both Ga & N-polar GaN layers is discussed in detail. We report device quality N-polar GaN epitaxial layers on non-miscut sapphire (0001) wafers by careful optimization of growth temperature. It is found that lower growth temperatures (800oC) are favorable for obtaining smooth N- polar GaN layers. In contrast, N-polar GaN layers grown at higher temperatures (1000 to 1080oC) are rough with hexagonal hillocks. Semiconductors Nitrides Gallium Nitride N-Polar Gallium Nitride Galllium Nitride Growth High Temperature Gallium Nitride Low Temperature Gallium Nitride GaN Materials Engineering

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