Ingénierie Quantique de Nanostructures À Base de Semi-conducteurs III-nitrures Pour L'optoélectronique Infrarouge PDF Download
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Author: Mark Beeler
Publisher:
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Languages : en
Pages : 0
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GaN/Al(Ga)N nanostructures have emerged during the last decade as promising materials for new intersubband (ISB) optoelectronics devices, with the potential to cover the whole infrared (IR) spectrum. These technologies rely on electron transitions between quantum-confined states in the conduction band of nanostructures -quantum wells (QWs), quantum dots (QDs), nanowires (NWs). The large conduction band offset between III-N compounds, and their sub-ps ISB recovery times make them appealing for ultrafast telecommunication devices and for fast IR optoelectronics in the 3-5 μm band. Furthermore, the large energy of GaN LO phonon (92 meV) opens prospects for room-temperature THz quantum cascade lasers and ISB devices covering the 5-10 THz band, inaccessible to GaAs. A variety of GaN-based ISB optoelectronic devices have recently been demonstrated, including photodetectors, switches and electro-optical modulators. However, a number of issues remain open, particularly concerning the extension towards longer wavelengths and the improvement of electrically pumped devices performance. One of the main challenges to extend the GaN-ISB technology towards the far-IR comes from the polarization-induced internal electric field, which imposes an additional confinement that increases the energetic distance between the electronic levels in the QWs. In order to surmount this constraint, I propose alternative multi-layer QW designs that create a pseudo-square potential profile. The robustness of the designs in terms of variations due to growth uncertainties, and the feasibility of their integration in devices architectures requiring resonant tunneling transport are discussed. Experimental realizations by molecular-beam epitaxy displaying TM-polarized THz absorption are presented. A quantum cascade laser design incorporating pseudo-square QWs is introduced. An alternative approach to obtain square potential profiles is the use of nonpolar orientations. In this thesis, I compare GaN/Al(Ga)N multi-quantum wells grown on a and m nonpolar bulk GaN showing that the best results in terms of structural and optical (interband and ISB) performance are obtained for m-plane structures. Room-temperature ISB absorption in the range of 1.5-5.8 μm is demonstrated, the longer wavelength limit being established by the second order of the Reststrahlen band in GaN. As ISB devices are pushed towards higher efficiencies, the control of carrier relaxation becomes a key aspect for device engineering. Longer intraband lifetimes have been proven to exist in laterally confined systems, which motivates studies to incorporate NWs as active elements in ISB devices. Furthermore, the large NW surface-to-volume ratio allows misfit strain to be elastically released, extending the viable active region size and composition beyond the limits of planar systems or QDs. In this thesis, I report the experimental observation of TM-polarized IR absorption assigned to the s-pz intraband transition in Ge-doped GaN/AlN nanodisks inserted in self-assembled GaN NWs. Results are compared with theoretical calculations accounting for the 3D strain distribution, surface charges and many-body effects.STAR.
Author: Mark Beeler
Publisher:
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Languages : en
Pages : 0
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Book Description
GaN/Al(Ga)N nanostructures have emerged during the last decade as promising materials for new intersubband (ISB) optoelectronics devices, with the potential to cover the whole infrared (IR) spectrum. These technologies rely on electron transitions between quantum-confined states in the conduction band of nanostructures -quantum wells (QWs), quantum dots (QDs), nanowires (NWs). The large conduction band offset between III-N compounds, and their sub-ps ISB recovery times make them appealing for ultrafast telecommunication devices and for fast IR optoelectronics in the 3-5 μm band. Furthermore, the large energy of GaN LO phonon (92 meV) opens prospects for room-temperature THz quantum cascade lasers and ISB devices covering the 5-10 THz band, inaccessible to GaAs. A variety of GaN-based ISB optoelectronic devices have recently been demonstrated, including photodetectors, switches and electro-optical modulators. However, a number of issues remain open, particularly concerning the extension towards longer wavelengths and the improvement of electrically pumped devices performance. One of the main challenges to extend the GaN-ISB technology towards the far-IR comes from the polarization-induced internal electric field, which imposes an additional confinement that increases the energetic distance between the electronic levels in the QWs. In order to surmount this constraint, I propose alternative multi-layer QW designs that create a pseudo-square potential profile. The robustness of the designs in terms of variations due to growth uncertainties, and the feasibility of their integration in devices architectures requiring resonant tunneling transport are discussed. Experimental realizations by molecular-beam epitaxy displaying TM-polarized THz absorption are presented. A quantum cascade laser design incorporating pseudo-square QWs is introduced. An alternative approach to obtain square potential profiles is the use of nonpolar orientations. In this thesis, I compare GaN/Al(Ga)N multi-quantum wells grown on a and m nonpolar bulk GaN showing that the best results in terms of structural and optical (interband and ISB) performance are obtained for m-plane structures. Room-temperature ISB absorption in the range of 1.5-5.8 μm is demonstrated, the longer wavelength limit being established by the second order of the Reststrahlen band in GaN. As ISB devices are pushed towards higher efficiencies, the control of carrier relaxation becomes a key aspect for device engineering. Longer intraband lifetimes have been proven to exist in laterally confined systems, which motivates studies to incorporate NWs as active elements in ISB devices. Furthermore, the large NW surface-to-volume ratio allows misfit strain to be elastically released, extending the viable active region size and composition beyond the limits of planar systems or QDs. In this thesis, I report the experimental observation of TM-polarized IR absorption assigned to the s-pz intraband transition in Ge-doped GaN/AlN nanodisks inserted in self-assembled GaN NWs. Results are compared with theoretical calculations accounting for the 3D strain distribution, surface charges and many-body effects.STAR.
Author: Fabien Guillot
Publisher:
ISBN:
Category :
Languages : fr
Pages : 184
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Ce travail a consisté en la croissance (par épitaxie à jets moléculaires) et la caractérisation de nanostructures à base de semiconducteurs nitrures (GaN, AlN et alliages) afin de développer de composants optoélectroniques avancés basés sur les transitions intrabandes pour la prochaine génération de systèmes de télécommunications à très haut débit. Une première série de résultats concerne la croissance de couches minces de nitrures, notamment celle des alliages d'AlGaN. D'après notre étude, la croissance de couches dont la fraction molaire d'Al reste en deçà de 35 % nécessite la présence d'un excès de Ga. Au delà, il est nécessaire d'utiliser l'In en tant que surfactant ou bien de réaliser des superalliages GaN/AlN. Des études du dopage Si de ce type de structures ont été menées. Nous avons ensuite étudié des structures à multicouches de puits quantiques GaN/AlN dopées Si. Celles-ci présentent les pics d'absorption ISB polarisée p à des longueurs d'onde de la gamme des télécommunications à température ambiante. L'effet de divers paramètres de croissance et de design a été étudié. L'analyse des caractérisations de ces échantillons a permis d'évaluer le champ électrique interne ainsi que l'offset de bande de conduction entre le GaN et l'AlN de nos structures. Concernant la synthèse des structures multicouches de boîtes quantiques GaN/AlN dopées Si, nous avons adapté la technique de croissance de ces structures pour minimiser la taille de boîtes, et ce, de manière à ce que leur absorption intrabande puisse atteindre les longueurs d'onde des télécommunications optiques. L'énergie du pic d'absorption des boîtes peut être ajustée en modifiant la quantité de GaN dans les boîtes, la température de croissance, et le temps d'interruption de croissance. Enfin, les résultats obtenus sur la réalisation de composants sont développés. Nous nous sommes focalisés sur les dispositifs basés sur l'absorption (photodétecteurs à puits et à boites quantiques, modulateurs électro-optiques) et l'émission de lumière infrarouge dans la gamme de longueurs d'onde des télécommunications. Des résultats prometteurs ont été obtenus sur l'ensemble de ces composants, ils forment une première étape vers la fabrication de composants pour les télécommunications à base de semiconducteurs nitrures.
Author: Yulia Kotsar
Publisher:
ISBN:
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Languages : fr
Pages : 0
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Ce mémoire résume des efforts dans la conception électronique, la croissance épitaxiale et la caractérisation des puits quantiques GaN/Al(Ga)N qui constituent la région active des composants inter-sous-bande (ISB) à base de semi-conducteurs nitrures pour l'optoélectronique dans l'infrarouge proche, moyen et lointain. Le dessin des puits quantiques GaN/Al(Ga)N pour ajuster la longueur d'onde d'absorption dans le spectre infrarouge a été réalisé en utilisant la méthode k.p à 8 bandes du logiciel Nextnano3 pour la résolution des équations de Schrödinger-Poisson. Les structures ont été synthétisées par épitaxie par jets moléculaires assistée par plasma (PAMBE). Les problèmes de gestion de la contrainte qui apparaissent liés au désaccord de maille pendant la croissance épitaxiale des hétérostructures GaN/Al(Ga)N ont été investigués par combinaison de techniques in-situ et ex-situ. La couche tampon optimale, la teneur en aluminium et les mécanismes de relaxation pendant la croissance par PAMBE ont été déterminés. Pour obtenir une absorption ISB efficace, on a besoin de niveaux élevés de dopage au silicium dans le puits quantiques, situation dans laquelle les théories à une particule conduisent à des déviations significatives par rapport aux résultats expérimentaux. Donc une étude du dopage au silicium des super-réseaux GaN/Al(Ga)N pour les régions spectrales infrarouges proche et moyen est présentée. Ce travail contient aussi une contribution à la compréhension de la technologie de photodétection à cascade quantique. Des résultats importants tels que l'obtention de photodétecteurs cascade fonctionnant à 1.5 μm et dans la plage spectrale de 3-5 μm sont démontrés. Finalement, on décrit la première observation de l'absorption ISB dans l'infrarouge lointain (4.2 THz) utilisant des nanostructures à base de semi-conducteurs nitrures.
Author: Chalermchai Himwas
Publisher:
ISBN:
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Languages : en
Pages : 0
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This work reports on the design, epitaxial growth, and the structural, and optical characterization of two types of nanostructures, namely AlGaN/AlN Stranski-Krastanov quantum dots (SK-QD) and AlGaN/AlN nanodisks (NDs) on GaN nanowires (NWs). These nanostructures were grown using plasma-assisted molecular beam epitaxy (PA-MBE) and were conceived to be the active media of electron-pumped ultraviolet (EPUV) emitters for water purification, operating in mid-ultraviolet range. The peak emission wavelength of three-dimensional SK-QD can be tuned in mid-ultraviolet range while keeping high internal quantum efficiency (IQE > 35%) by modifying the Al composition and the QD geometry. The efficient carrier confinement was confirmed by the stability of the photoluminescence intensity and decay time with temperature. The optimal deposited amount of AlGaN in AlGaN/AlN QDs which grants maximum luminescence at room temperature was determined by finding a compromise between the designs providing maximum IQE and maximum QD density. The effect of the variation of the QD height/base-diameter ratio on the interband and intraband optical properties was explored by fitting the experimental data with three-dimensional calculations of the band diagram and quantum levels. Regarding AlGaN/AlN NDs on GaN NWs, the Al-Ga intermixing at Al(Ga)N/GaN interfaces and the alloy inhomogeneity in AlGaN/AlN NDs are attributed to the strain relaxation process. This interpretation was proved by correlation of experimental data with three-dimensional strain distribution calculations performed on structures that imitate the real growth sequence. Despite the challenge of inhomogeneity, the emission wavelength of AlGaN/AlN NDs can be tuned in mid-ultraviolet range while preserving high IQE by adjusting the ND thickness and Al content. A prototype of EPUV emitter was fabricated using the AlGaN/AlN SK-QDs active region with proposed optimal design of active region thickness, AlN barrier thickness, and amount of AlGaN in each QD layer. For this first device, SiC was used as a substrate to prevent problems associated to charge or heat evacuation. A water purification test by such prototype EPUV emitter was carried out by irradiating E-coli bacteria, showing that all the specimens were successfully purified at the predicted ultraviolet dose.
Author: Agnes Buka
Publisher: World Scientific
ISBN: 1848167997
Category : Science
Languages : en
Pages : 299
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Book Description
The book intends to give a state-of-the-art overview of flexoelectricity, a linear physical coupling between mechanical (orientational) deformations and electric polarization, which is specific to systems with orientational order, such as liquid crystals. Chapters written by experts in the field shed light on theoretical as well as experimental aspects of research carried out since the discovery of flexoelectricity. Besides a common macroscopic (continuum) description the microscopic theory of flexoelectricity is also addressed. Electro-optic effects due to or modified by flexoelectricity as well as various (direct and indirect) measurement methods are discussed. Special emphasis is given to the role of flexoelectricity in pattern-forming instabilities. While the main focus of the book lies in flexoelectricity in nematic liquid crystals, peculiarities of other mesophases (bent-core systems, cholesterics, and smectics) are also reviewed. Flexoelectricity has relevance to biological (living) systems and can also offer possibilities for technical applications. The basics of these two interdisciplinary fields are also summarized.
Author: Jerome V. Moloney
Publisher: Springer Science & Business Media
ISBN: 9780387985817
Category : Business & Economics
Languages : en
Pages : 270
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Book Description
Mathematical methods play a significant role in the rapidly growing field of nonlinear optical materials. This volume discusses a number of successful or promising contributions. The overall theme of this volume is twofold: (1) the challenges faced in computing and optimizing nonlinear optical material properties; and (2) the exploitation of these properties in important areas of application. These include the design of optical amplifiers and lasers, as well as novel optical switches. Research topics in this volume include how to exploit the magnetooptic effect, how to work with the nonlinear optical response of materials, how to predict laser-induced breakdown in efficient optical devices, and how to handle electron cloud distortion in femtosecond processes.
