Global ETD Search

91	Characterization of AlGaN HEMT structures Lundskog, Anders January 2007 (has links) <p>During the last decade, AlGaN High Electron Mobility Transistors (HEMTs) have been intensively studied because their fundamental electrical properties make them attractive for highpower microwave device applications. Despite much progress, AlGaN HEMTs are far from fully understood and judged by the number of published papers the understanding of advanced structures is even poorer. This work is an exploration of the electrical and structural properties of advanced HEMT structure containing AlN exclusionlayer and double heterojunctions. These small modifications had great impact on the electrical properties.</p><p>In this work, AlGaN HEMT structures grown on SiC substrates by a hot-wall MOCVD have been characterized for their properties using optical microscopy, scanning electron microscopy, transmission electron microscopy, capacitance/voltage, eddy-current resistivity, and by homebuilt epi-thickness mapping equipment.</p><p>A high electron mobility of 1700 [cm2/Vs] was achieved in an AlN exclusion-layer HEMT. A similar electron mobility of 1650 [cm2/Vs] was achieved in a combination of a double heterojunction and exclusion-layer structure. The samples had approximately the same electron mobility but with a great difference: the exclusion-layer version gave a sheet carrier density of 1.581013 [electrons/cm2] while the combination of double heterojunction and exclusion-layer gave 1.071013 [electrons/cm2]. A second 2DEG was observed in most structures, but not all, but was not stable with time.</p><p>The structures we grew during this work were also simulated using a one-dimensional Poisson-Schrödinger solver and the simulated electron densities were in fairly good agreement with the experimentally obtained. III-nitride materials, the CVD concept, and the onedimensional solver are shortly explained.</p> HEMT Hot-Wall MOCVD GaN AlGaN AlN exclusionlayer Double heterojunction 1D Poisson-Schrödinger Material physics with surface physics Materialfysik med ytfysik
92	Analysis of GaN/AlxGa1−xN Heterojunction Dual-Band Photodetectors Using Capacitance Profiling Techniques Byrum, Laura E. 01 December 2009 (has links) Capacitance-voltage-frequency measurements on n+-GaN/AlxGa1−xN UV/IR dual-band detectors are reported. The presence of shallow Si-donor, deep Si-donor, and C-donor/N-vacancy defect states were found to significantly alter the electrical characteristics of the detectors. The barrier Al fraction was found to change the position of the interface defect states relative to the Fermi level. The sample with Al fraction of 0.1 shows a distinct capacitance-step and hysteresis, which is attributed to C-donor/N-vacancy electron trap states located above the Fermi level (200 meV) at the heterointerface; whereas, the sample with Al fraction of 0.026 shows negative capacitance and dispersion, indicating C-donor/N-vacancy and deep Si-donor defect states located below the Fermi level (88 meV). When an i-GaN buffer layer was added to the structure, an anomalous high-frequency capacitance peak was observed and attributed to resonance scattering due to hybridization of localized Si-donor states in the band gap with conduction band states at the i-GaN/n+-GaN interface. Infrared detectors Dual-band Ultraviolet detectors III-V material GaN AlGaN Heterojunction Workfunction Photoemission Impurity states Capacitance Negative capacitance Capacitance hysteresis Astrophysics and Astronomy Physics
93	Study of III-N heterostructure field effect transistors Narayan, Bravishma 01 September 2010 (has links) This thesis describes the design, fabrication and characterization of AlGaN/GaN Heterostructure Field E ect Transistors (HFETs) grown by a Metal Organic Chemical Vapor Deposition (MOCVD) on sapphire substrates. The objective of this research is to develop AlGaN/GaN power devices with high breakdown voltage (greater than 1 kV) and low turn-on resistance. Various characteristics such as current drive (Idss), transconductance (gm) and threshold voltage (Vth) have also been measured and the results have been discussed. Two major challenges with the development of high breakdown voltage AlGaN/GaN HFETs in the past have been high material defect density and non-optimized fabrication technologies which gives rise to bu er leakage and surface leakage, respectively. In this thesis, mesa isolation, ohmic and gate metal contacts, and passivation techniques, have been discussed to improve the performance of these power transistors in terms of low contact resistance and low gate leakage. The relationship between breakdown voltage and Rds(ON)A with respect to the gate-drain length (Lgd) is also discussed. First, unit cell devices were designed (two-fingered cells with Wg = 100, 300, 400 m) and characterized, and then they were extended to form large area devices (upto Wg = 40 mm). The design goals were classied into three parts: - High Breakdown Voltage: This was achieved by designing devices with variations in Lgd, - Low turn-on resistance: This was achieved by optimizing the annealing temperatures as well as incorporating additional thick metal pads, as well as optimizing the passivation etch recipe, - Low Gate Leakage: The gate leakage was reduced signicantly by using a gate metal with a larger barrier height. All devices with Lgd larger than 10 m exhibited excellent breakdown voltage characteristics of over 800 V, and it progressed as the Lgd increased. The turn-on resistance was also reduced signicantly below 20 m-cm2, for devices with Lgd = 15, 25, and 20 m. The gate leakage was measured for all devices upto 200 V, and was in the range of 10-100 nA, which is one of the best values reported for multi-ngered devices with Lgd in the range of 2.4-5 mm. Some of the key challenges faced in fabrication were determining a better gate metal layer to reduce gate leakage, optimizing the passivation via etch recipe, and reducing surface leakage. Breakdown voltage Gate Drain Source HFET Transistor AlGaN/GaN Turn-on resistance Gate leakage Saturation current Threshold voltage Metal organic chemical vapor deposition Field-effect transistors
94	深紫外分光技術の確立とAlGaN系量子井戸の再結合ダイナミクスの研究岩田, 佳也 23 March 2015 (has links) Kyoto University (京都大学) / 0048 / 新制・課程博士 / 博士(工学) / 甲第18948号 / 工博第3990号 / 新制\|\|工\|\|1614 / 31899 / 京都大学大学院工学研究科電子工学専攻 / (主査)教授川上養一, 教授野田進, 教授木本恒暢 / 学位規則第4条第1項該当深紫外 AlGaN 共焦点光学顕微鏡内部量子効率 LOフォノン 500
95	Characterization of AlGaN HEMT structures Lundskog, Anders January 2007 (has links) During the last decade, AlGaN High Electron Mobility Transistors (HEMTs) have been intensively studied because their fundamental electrical properties make them attractive for highpower microwave device applications. Despite much progress, AlGaN HEMTs are far from fully understood and judged by the number of published papers the understanding of advanced structures is even poorer. This work is an exploration of the electrical and structural properties of advanced HEMT structure containing AlN exclusionlayer and double heterojunctions. These small modifications had great impact on the electrical properties. In this work, AlGaN HEMT structures grown on SiC substrates by a hot-wall MOCVD have been characterized for their properties using optical microscopy, scanning electron microscopy, transmission electron microscopy, capacitance/voltage, eddy-current resistivity, and by homebuilt epi-thickness mapping equipment. A high electron mobility of 1700 [cm2/Vs] was achieved in an AlN exclusion-layer HEMT. A similar electron mobility of 1650 [cm2/Vs] was achieved in a combination of a double heterojunction and exclusion-layer structure. The samples had approximately the same electron mobility but with a great difference: the exclusion-layer version gave a sheet carrier density of 1.581013 [electrons/cm2] while the combination of double heterojunction and exclusion-layer gave 1.071013 [electrons/cm2]. A second 2DEG was observed in most structures, but not all, but was not stable with time. The structures we grew during this work were also simulated using a one-dimensional Poisson-Schrödinger solver and the simulated electron densities were in fairly good agreement with the experimentally obtained. III-nitride materials, the CVD concept, and the onedimensional solver are shortly explained. HEMT Hot-Wall MOCVD GaN AlGaN AlN exclusionlayer Double heterojunction 1D Poisson-Schrödinger Material physics with surface physics Materialfysik med ytfysik
96	Multiband Detectors and Application of Nanostructured Anti-Reflection Coatings for Improved Efficiency Jayasinghe, J. A. Ranga C 20 December 2012 (has links) This work describes multiband photon detection techniques based on novel semiconductor device concepts and detector designs with simultaneous detection of dierent wavelength radiation such as UV and IR. One aim of this investigation is to examine UV and IR detection concepts with a view to resolve some of the issues of existing IR detectors such as high dark current, non uniformity, and low operating temperature and to avoid having additional optical components such as filters in multiband detection. Structures were fabricated to demonstrate the UV and IR detection concepts and determine detector parameters: (i) UV/IR detection based on GaN/AlGaN heterostructures, (ii) Optical characterization of p-type InP thin films were carried out with the idea of developing InP based detectors, (iii) Intervalence band transitions in InGaAsP/InP heterojunction interfacial workfunction internal photoemission (HEIWIP) detectors. Device concepts, detector structures, and experimental results are discussed. In order to reduce reflection, TiO2 and SiO2 nanostructured thin film characterization and application of these as anti-reflection coatings on above mentioned detectors is also discussed. Infrared detectors UV/IR Dual-band detectors Split-off band GaAs AlGaAs GaN AlGaN InP InGaAsP TiO2 nanorods Anti-reflection coatings
97	De l'étude en bruit basse fréquence à la conception d'un oscillateur en bande-X à partir de transistors AlGaN/GaN HEMT Soubercaze-Pun, Geoffroy 26 January 2007 (has links) (PDF) L'objectif de ce travail est d'étudier les transistors à effet de champ à haute mobilité électronique (HEMT) réalisés en Nitrure de Gallium par des mesures en bruit basse fréquence et de réaliser un oscillateur à faible bruit de phase en bande-X. Dans la première partie, nous décrivons succinctement les propriétés du matériau, le transistor ainsi que les sources de bruit basses susceptibles d'êtres présentes dans une structure de type HEMT. La méthodologie de mesure et le banc de bruit basse fréquence sont présentés. Une étude comparative est réalisée sur les comportements en bruit basse fréquence des composants épitaxiés sur différents substrats (Si, SiC, Al2O3). Enfin, une les variations de l'index de fréquence g du bruit en 1/fg relevées sur certains composants sont corrélées au mécanisme de transport des électrons dans la structure : pour cela, nous avons confronté les mesures en bruit basse fréquence avec des simulations physiques. La seconde partie s'intéresse aux composants épitaxiés sur un substrat de Carbure de Silicium. Une méthodologie d'extraction de composantes mathématiques du spectre de bruit basse fréquence est présentée puis validée. Des études en fonction de la polarisation et de la température ont permis de découvrir l'origine des pièges et de les localiser. Enfin, une corrélation avec une étude physique (SIMS) est présentée. Dans la troisième partie, nous développons un modèle large signal afin de réaliser un démonstrateur en bande X. Les performances à l'état de l'art de l'oscillateur sont ensuite présentées (POUT=20dBm, Lf(100kHz)=-105 dBc/Hz à 10 GHz). HEMT AlGaN/GaN Bruit basse fréquence extraction des sources de bruit Modélisation Large Signal Oscillateur bande-X
98	Propriétés structurales et optiques de nanostructures III-N semiconductrices à grand gap : nanofils d'AlxGa1-xN synthétisés par épitaxie par jets moléculaires et nanostructures de nitrure de bore. Pierret, A. 25 October 2013 (has links) (PDF) Ce travail de thèse s'intéresse aux propriétés structurales et optiques de semiconducteurs à grand gap de nitrure d'éléments III (AlxGa1-xN et h-BN), émettant dans l'ultraviolet (4-6 eV). Les propriétés des nano-objets étant modifiées par la réduction de dimensionnalité, un point central de ce travail a consisté à étudier des nanostructures de ces matériaux (nanofils d'AlN et d'AlxGa1-xN, nanotubes et nanofeuillets de BN). Un soin particulier a aussi été apporté à la corrélation à l'échelle nanométrique, entre la structure et la luminescence. Dans un premier temps, les nanofils d'AlxGa1-xN ont été synthétisés par épitaxie par jets moléculaires, sur des nanofils de GaN afin de promouvoir la croissance de nanostructures 1D non coalescées. Nous montrons que le gallium s'incorpore difficilement, aboutissant à des nanofils d'un alliage fortement inhomogène à plusieurs échelles (de l'unité à la centaine de nanomètre). Ces inhomogénéités influencent grandement les propriétés optiques, dominées par des états localisés. L'ensemble des résultats nous a permis de proposer un mécanisme de croissance de ces nanofils. Dans un deuxième temps, les propriétés des nanostructures de BN ont été comparées à celles du matériau massif (le BN hexagonal). Nous montrons que jusqu'à 6 couches les nanofeuillets présentent une luminescence similaire au h-BN. Cela indique une faible influence de la réduction de dimensionnalité dans le h-BN, contrairement aux nanostructures de GaN ou d'AlN. Enfin, nous montrons que les principaux nanotubes étudiés dans ce travail, multiparois, présentent une structure complexe, micro-facettée, et que les défauts sont probablement responsables de la luminescence observée. NANOFILS NANOTUBE SEMICONDUCTEUR NITRURE ALGAN BN EPITAXIE JET MOLECULAIRE PHOTOLUMINESCENCE CATHODOLUMINESCENCE MICROSCOPIE ELECTRONIQUE
99	Kvantitativní analýza matricových prvků metodami SIMS a LEIS / Quantitative analysis of matrix elements using SIMS and LEIS methods Staněk, Jan January 2019 (has links) This thesis studies comparison and connection of two spectrometric methods – low energy ion scattering spektrometry (LEIS) and secondary ion mass spectrometry (SIMS). SIMS method, despite its many positive qualities, suffers of so called matrix effect, which makes quantifiaction of data very difficult. LEIS method on the other hand is immune to this effect and so it’s suitable completion of SIMS method. As a convenient sample have been chosen AlGaN samples with various concentration of gallium and aluminium. In the first part of thesis is introduced physical essence of SIMS and LEIS method, experimental details and studied samples. In second part of the thesis there’s a description of measurements and comparison of data gained by each method.
100	High Power GaN/AlGaN/GaN HEMTs Grown by Plasma-Assisted MBE Operating at 2 to 25 GHz Waechtler, Thomas, Manfra, Michael J, Weimann, Nils G, Mitrofanov, Oleg 27 April 2005 (has links) Heterostructures of the materials system GaN/AlGaN/GaN were grown by molecular beam epitaxy on 6H-SiC substrates and high electron mobility transistors (HEMTs) were fabricated. For devices with large gate periphery an air bridge technology was developed for the drain contacts of the finger structure. The devices showed DC drain currents of more than 1 A/mm and values of the transconductance between 120 and 140 mS/mm. A power added efficiency of 41 % was measured on devices with a gate length of 1 µm at 2 GHz and 45 V drain bias. Power values of 8 W/mm were obtained. Devices with submicron gates exhibited power values of 6.1 W/mm (7 GHz) and 3.16 W/mm (25 GHz) respectively. The rf dispersion of the drain current is very low, although the devices were not passivated. / Heterostrukturen im Materialsystem GaN/AlGaN/GaN wurden mittels Molekularstrahlepitaxie auf 6H-SiC-Substraten gewachsen und High-Electron-Mobility-Transistoren (HEMTs) daraus hergestellt. Für Bauelemente mit großer Gateperipherie wurde eine Air-Bridge-Technik entwickelt, um die Drainkontakte der Fingerstruktur zu verbinden. Die Bauelemente zeigten Drainströme von mehr als 1 A/mm und Steilheiten zwischen 120 und 140 mS/mm. An Transistoren mit Gatelängen von 1 µm konnten Leistungswirkungsgrade (Power Added Efficiency) von 41 % (bei 2 GHz und 45 V Drain-Source-Spannung) sowie eine Leistung von 8 W/mm erzielt werden. Bauelemente mit Gatelängen im Submikrometerbereich zeigten Leistungswerte von 6,1 W/mm (7 GHz) bzw. 3,16 W/mm (25 GHz). Die Drainstromdispersion ist sehr gering, obwohl die Bauelemente nicht passiviert wurden. info:eu-repo/classification/ddc/621 ddc:621 info:eu-repo/classification/ddc/537 ddc:537 HEMT AlGaN GaN High Electron Mobility Transistor MBE heterostructure

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