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281	Influence des défauts sur les propriétés optiques et électroniques des nanoparticules de ZnO Taïnoff, Dimitri 07 December 2009 (has links) (PDF) L'objectif de cette étude est de mieux comprendre le rôle joué par les défauts dans les propriétés optiques et électroniques des nanostructures d'oxyde de zinc. Pour ce faire, nous avons synthétisé des nanoparticules d'oxyde de zinc de 6 à 18 nm de diamètres pouvant être considérées comme modèle en terme de stœchiométrie, de cristallinité et de qualité de surface par une méthode physique originale : la Low Energy Cluster Beam Deposition.La caractérisation optique des défauts présents dans les nanoparticules de ZnO a été faite grâce à l'analyse des spectres d'émission visible et UV à différentes températures [10K-300K]. En particulier la luminescence excitonique à 3,31 eV, qui est un sujet controversé, a été étudiée en comparant la luminescence excitonique d'échantillons structurés à différentes échelles (nanoparticules, microcristaux et monocristal). Les temps de déclins très rapides des défauts donneurs ont été étudiés par spectroscopie à décalage de fréquence au CELIA à Bordeaux révélant une dépendance en fonction de la taille des NPs du type Giant Oscillator Strenght.Les propriétés de transport électronique des couches minces de NPs, naturellement dopées n, ont été caractérisées grâce à des expériences σ(T). Différents scénarios sont proposés pour expliquer les résultats des expériences de conductivité, et discutés en fonction des propriétés optiques des couches et de leur morphologie. En particulier, il est montré que la surface des NPs, très réactive, influence fortement le transport, ce qui laisse entrevoir la possibilité d'utiliser ces films nanostructurés comme capteurs de gaz. [PHYS:PHYS] Physics/Physics Nanoparticules ZnO Photoluminescence Défauts Couplage exciton-phonon MET Transport électronique VUV
282	Nanoscale Characterisation of Barriers to Electron Conduction in ZnO Varistor Materials Elfwing, Mattias January 2002 (has links) <p>The work presented in this thesis is concerned with the microstructure of zinc oxide varistor materials used in surge protecting devices. This class of material has been characterised with special emphasis on the functional microstructure and the development of the microstructure during sintering. Several different techniques have been used for the analysis, especially scanning electron microscopy (SEM) in combination with electron beam-induced current (EBIC) analysis and <i>in-situ</i> studies of heat-treatment experiments and transmission electron microscopy (TEM) in combination with energy dispersive X-ray spectrometry (EDS) and electron holography. </p><p>Detailed TEM analyses using primarily centred dark-field imaging of grain boundaries, especially triple and multiple grain junctions, were used to reveal the morphological differences between the various Bi<sub>2</sub>O<sub>3</sub> phases. The triple and multiple grain junctions were found to exhibit distinct differences in morphology, which could be attributed the difference in structure of the crystalline Bi<sub>2</sub>O<sub>3</sub> polymorphs present in the junctions. </p><p>Electrical measurements were performed on individual ZnO/ZnO grain boundaries using EBIC in the SEM. The EBIC signal was found to depend strongly on the geometric properties of the interface and also on the symmetry of the depletion region at the interface. A symmetric double Schottky barrier was never observed in the experiments, but instead barriers with clear asymmetry in the depletion region. Experimental results together with computer simulations show that reasonably small differences in the deep donor concentrations between grains could be responsible for this effect.</p><p>Electron holography in the TEM was used to image the electrostatic potential variation across individual ZnO/ZnO interfaces. The sign of the interface charge, the barrier height (about 0.8 eV) and the depletion region width (100 to 150 nm) were determined from holography data. Asymmetries of the depletion region were also found with this technique. </p><p>The full sintering process of doped ZnO powder granules was studied <i>in-situ</i> in the environmental SEM. The densification and grain growth processes were studied through the sintering cycle. The formation of a functional microstructure in ZnO varistor materials was found to depend strongly on the total pressure.</p> Materials science ZnO varistor material TEM SEM EBIC ESEM electron holography Materialvetenskap Materials science Teknisk materialvetenskap
283	Nanofils de semiconducteurs à grande énergie de bande interdite pour des applications optoélectroniques Jacopin, Gwenolé 26 September 2012 (has links) (PDF) Depuis le début des années 2000, une vaste classe de nanofils de nitrures d'éléments III et de ZnO peut être synthétisée avec un excellent contrôle des propriétés de dopage et de composition. La géométrie spécifique de ces nanofils permet de faire croître des hétérostructures radiales et axiales qui ont des propriétés optiques et de transport très avantageuses par rapport aux couches minces. Ces propriétés en font des candidats prometteurs pour la réalisation d'une nouvelle génération de dispositifs plus efficaces (LEDs, photodétecteurs,...). Pour cela, il est indispensable de comprendre les nouveaux effets induits par la géométrie particulière de ces nanostructures : c'est l'objet de cette thèse. Dans une première partie, je présente une étude des propriétés optiques de nanofils de semiconducteurs à grande énergie de bande interdite. J'analyse d'abord l'effet de la contrainte sur les propriétés d'émission des nanofils cœur-coquille GaN/AlGaN. En particulier, je mets en évidence le croisement des bandes de valence et son influence sur les propriétés optiques des nanofils. Ensuite, je me focalise sur l'effet du confinement quantique et les propriétés de polarisation dans les nanofils hétérostructurés de nitrures d'éléments III. Dans une seconde partie, je m'intéresse à la réalisation et à la caractérisation de dispositifs à base de nanofils de nitrures d'éléments III et de ZnO. J'expose tout d'abord la modélisation et l'étude expérimentale de photodétecteurs à ensemble de nanofils en mettant en avant l'influence des états de surface sur leur réponse. Je m'intéresse ensuite aux propriétés de transport dans des nanofils uniques de nitrures d'éléments III hétérostructurés. Je montre, en particulier, que ces hétérostructures sont le siège d'une résistance différentielle négative. Enfin, je présente la réalisation et la caractérisation de photodétecteurs et de LEDs utilisant des nanofils uniques InGaN/GaN cœur-coquille. Un modèle électrique équivalent permet de rendre compte du comportement observé. Nitrures d'éléments III ZnO Nanofil Photoluminescence Électroluminescence
284	Nanoscale Characterisation of Barriers to Electron Conduction in ZnO Varistor Materials Elfwing, Mattias January 2002 (has links) The work presented in this thesis is concerned with the microstructure of zinc oxide varistor materials used in surge protecting devices. This class of material has been characterised with special emphasis on the functional microstructure and the development of the microstructure during sintering. Several different techniques have been used for the analysis, especially scanning electron microscopy (SEM) in combination with electron beam-induced current (EBIC) analysis and in-situ studies of heat-treatment experiments and transmission electron microscopy (TEM) in combination with energy dispersive X-ray spectrometry (EDS) and electron holography. Detailed TEM analyses using primarily centred dark-field imaging of grain boundaries, especially triple and multiple grain junctions, were used to reveal the morphological differences between the various Bi2O3 phases. The triple and multiple grain junctions were found to exhibit distinct differences in morphology, which could be attributed the difference in structure of the crystalline Bi2O3 polymorphs present in the junctions. Electrical measurements were performed on individual ZnO/ZnO grain boundaries using EBIC in the SEM. The EBIC signal was found to depend strongly on the geometric properties of the interface and also on the symmetry of the depletion region at the interface. A symmetric double Schottky barrier was never observed in the experiments, but instead barriers with clear asymmetry in the depletion region. Experimental results together with computer simulations show that reasonably small differences in the deep donor concentrations between grains could be responsible for this effect. Electron holography in the TEM was used to image the electrostatic potential variation across individual ZnO/ZnO interfaces. The sign of the interface charge, the barrier height (about 0.8 eV) and the depletion region width (100 to 150 nm) were determined from holography data. Asymmetries of the depletion region were also found with this technique. The full sintering process of doped ZnO powder granules was studied in-situ in the environmental SEM. The densification and grain growth processes were studied through the sintering cycle. The formation of a functional microstructure in ZnO varistor materials was found to depend strongly on the total pressure. Materials science ZnO varistor material TEM SEM EBIC ESEM electron holography Materialvetenskap Materials science Teknisk materialvetenskap
285	Organic-Inorganic Hetero Junction White Light Emitting Diode : N-type ZnO and P-type conjugated polymer Lubuna Beegum, Shafeek January 2008 (has links) The purpose of this thesis work is to design and fabricates organic-inorganic hetero junction White Light Emitting Diode (WLED). In this WLED, inorganic material is n- type ZnO and organic material is p-type conjugated polymer. The first task was to synthesise vertically aligned ZnO nano-rods on glass as well as on plastic substrates using aqueous chemical growth method at a low temperature. The second task was to find out the proper p- type organic material that gives cheap and high efficient WLED operation. The proposed polymer shouldn’t create a high barrier potential across the interface and also it should block electrons entering into the polymer. To optimize the efficiency of WLED; charge injection, charge transport and charge recombination must be considered. The hetero junction organic-inorganic structures have to be engineered very carefully in order to obtain the desired light emission. The layered structure is composed of p-polymer/n-ZnO and the recombination has been desired to occur at the ZnO layer in order to obtain white light emission. Electrical characterization of the devices was carried out to test the rectifying properties of the hetero junction diodes. iv WLED ZnO Zinc Oxide Organic Inorganic Conjucated Polymer LED ACG Semiconductor physics Halvledarfysik
286	Studies On The Growth And Characterization Of II-VI Semiconductor Nanostructures By Evaporation Methods Yuvaraj, D 07 1900 (has links) In recent years, there has been growing interests on II-VI semiconductor nanostructures, which are suitable for applications in electronics and optoelectronic devices such as solar cells, UV lasers, sensors, light emitting diodes and field emission displays. II-VI semiconductor nanostructures with different morphologies such as wires, belts, rods, tubes, needles, springs, tetrapods, plates, hierarchical structures and so on, have been widely grown by vapor transport methods. However the process conditions used for the growth of nanostructures still remains incompatible for device fabrication. The realization of practical nanoscale devices using nanostructured film depends mainly on the availability of low cost and lower processing temperatures to manufacture high purity nanostructures on a variety of substrates including glass and polymer. In this thesis work, studies have been made on the growth and characterization of II-VI semiconductor nanostructures prepared at room temperature, under high vacuum, without employing catalysts or templates. (i) ZnO nanostructured films with different morphology such as flowers, needles and shrubs were deposited at room temperature on glass and polymer substrates by plasma assisted reactive process. (ii) Zn/ZnO core/shell nanowires were grown on Si substrates under optimized oxygen partial pressure. Annealing of this core shell nanowire in high vacuum resulted in the formation of ZnO nanocanals. (iii) ZnS and ZnSe nano and microstructures were grown on Si substrates under high vacuum by thermal evaporation. The morphology, structural, optical properties and composition of these nano and microstructures were investigated by XRD, SEM, TEM, Raman, PL and XPS. The growth mechanism behind the formation of the different nanostructures has been explained on the basis of vapour-solid (VS) mechanism. Evaporation Method Optoelectronic Devices Semiconductor Nanostructures - Growth Zinc Oxide Nanostructures Zinc Sulfide Nanostructures Zinc Selenide Nanostructures Nanostructured Films - Deposition Zinc Oxide Nanostructured Films ZnO Nanostructured Films ZnO Nanostructures Activated Reactive Evaporation ZnO Films ZnO Nanoneedles Thermal Evaporation Polymer Substrates Zn Microstructures ZnS Semiconductors-Nanostructures
287	Surface and Interface Studies of ZnO using Reactive Dynamics Simulation Raymand, David January 2010 (has links) About 90% of all chemicals are produced with the help of catalysts, substances with the ability to accelerate reactions without being consumed. Metal oxides play a prominent role in catalysis, since they are able to act reversibly in many chemical processes. Zink oxide (ZnO) is used to catalyse a number of industrially important reactions. For many of these reactions water is present as a reactant, product, or byproduct. The surface structure has a significant impact on the catalytic activity. However, currently, no experimental method simultaneously offers the spatial and temporal resolution to directly follow a catalytic process. This thesis explores surface structure dependent dynamical behavior for ZnO surfaces, nanoparticles, and water interfaces, using the computational chemistry method Molecular Dynamics, which enables detailed studies of structural and dynamical processes. Quantum mechanical (QM) calculations have been performed to obtain the energetics of the materials as a function of structure. This data has been used to parametrize reactive force-fields (ReaxFF), since the catalytic processes require both far larger and longer simulations than the capabilities of QM calculations on current computers. The simulations show that when steps are present on the surface, during crystal growth of ZnO, the creation of energetically favorable structures is accelerated. At the ZnO - water interface, structures that favor hydrogen bonding is promoted. At low, monolayer, coverage water adsorbs both molecularly and dissociatively, whereas at high coverage dissociated adsorption is favored. During evaporation from the monolayers, the ratio of dissociated and molecular water is preserved. Surface steps stabilizes the dissociated state as well as increases the rate of dissociation. The dynamical properties of ZnO nanoparticles were explored using Raman measurements and simulation. In both simulation and experiment certain vibrations were suppressed in the nanoparticles, compared to bulk. The simulations show that a narrow surface region lack the bulk-specific vibrations. catalysis molecular dynamics force-fields metal oxide ZnO dynamical effects on reactivity Inorganic chemistry Oorganisk kemi
288	An intracellular glucose biosensor based on nanoflake ZnO Fulati, Alimujiang, Usman Ali, Syed M., Asif, Muhammad H., Hassan Alvi, Naveed Ul, Willander, Magnus, Brännmark, Cecilia, Strålfors, Peter, Börjesson, Sara I., Elinder, Fredrik, Danielsson, Bengt January 2010 (has links) In this study, an improved potentiometric intracellular glucose biosensor was fabricated with immobilization of glucose oxidase on a ZnO nanoporous material. The ZnO nanoporous material with a wall thickness around 200 nm was grown on the tip of a borosilicate glass capillary and used as a selective intracellular glucose sensor for the measurement of glucose concentrations in human adipocytes and frog oocytes. The results showed a fast response within 4 s and a linear glucosedependent electrochemical response over a wide range of glucose concentration (500 nM-10 mM). The measurements of intracellular glucose concentrations with our biosensor were consistent with the values of intracellular glucose concentrations reported in the literature. The sensor also demonstrated its capability by detecting an increase in the intracellular glucose concentration induced by insulin. We found that the ZnO nanoporous material provides sensitivity as high as 1.8 times higher than that obtained using ZnO nanorods under the same conditions. Moreover, the fabrication method in our experiment is simple and the excellent performance of the developed nanosensor in sensitivity, stability, selectivity, reproducibility and anti-interference was achieved. All these advantageous features of this intracellular glucose biosensor based on functionalised ZnO nanoporous material compared to ZnO nanorods demonstrate a promising way of enhancing glucose biosensor performance to measure reliable intracellular glucose concentrations within single living cells. / <p>Original Publication:Alimujiang Fulati, Syed M. Usman Ali, Muhammad H. Asif, Naveed Ul Hassan Alvi, Magnus Willander, Cecilia Brännmark, Peter Strålfors, Sara I. Börjesson and Fredrik Elinder, An intracellular glucose biosensor based on nanoflake ZnO, 2010, Sensors and actuators. B, Chemical, (150), 2, 673-680.http://dx.doi.org/10.1016/j.snb.2010.08.021Copyright: Elsevier Science B.V., Amsterdam.http://www.elsevier.com/</p> Glucose oxidase (GOD) Intracellular Potentiometric biosensor Nanoflake ZnO Nafion membrane NATURAL SCIENCES NATURVETENSKAP
289	Spectroscopic study of transition metal compounds. Choudhury, Sanjukta 30 August 2010 The electronic structure of some transition metal compounds, specifically, Ca-doped LaMnO3, fundamental Mn oxides (MnO, Mn2O3, Mn3O4, and MnO2), and Fe-doped ZnO is studied using a combination of soft X-ray spectroscopy and atomic multiplet calculations. X-ray absorption spectroscopy (XAS) and X-ray emission spectroscopy (XES) are used as experimental tools to probe the unoccupied and occupied partial density of electronic states,respectively.<p> Ca-doped LaMnO3 perovskites have attracted great attention due to their colossal magnetoresistance and a wide range of magnetic and structural transitions. The magnetic and charge transport properties of these perovskites are directly related with Mn 3d-occupancy or Mn-valency and therefore, an investigation of the Mn-valence at Ca-doped LaMnO3 system is important. In this system, the Mn-valency is generally considered as a mixture of Mn3+ and Mn4+. But my research suggests the presence of Mn2+ at the surface of Ca-doped LaMnO3 samples. It is observed that increasing Ca-doping decreases Mn2+ concentration, and conversely, increases Mn3+ concentration. High temperature annealing at 1000 °C in air leads to the full reduction of surface Mn2+. Mechanisms for these observations are proposed in this study.<p> Mn oxides (MnO, Mn2O3, Mn3O4, and MnO2) are often used as reference standards for determining the Mn-valency in Mn-related complex systems and therefore a detailed understanding of their electronic structure is necessary. The Mn L2,3 XAS and O K XAS are measured for the four Mn oxides consisting of three common Mn oxidation states (Mn2+ in MnO, Mn3+ in Mn2O3, mixture of Mn2+ and Mn3+ in Mn3O4, and Mn4+ in MnO2). A significant energy shift with a systematic trend is observed in measured Mn L2,3 and O K absorption edges. These energy shifts are identified as a characteristic shift for different Mn oxidation states. Mn L2,3 Resonant Inelastic X-ray Scattering (RIXS) spectroscopy is demonstrated as a powerful tool in describing low energy excitations, e.g. d-d excitations and charge-transfer excited states in Mn oxides. For the first time, a RIXS study of Mn2O3,Mn3O4, and MnO2 is accomplished. Atomic multiplet calculations are used to successfully reproduce the energy positions and intensity variations of d-d excitation peaks observed in the experiment, and thus to describe the experimental RIXS spectra.<p> Finally, the local electronic structure of Fe implanted ZnO samples, a useful diluted magnetic semiconductor for spintronics, is investigated to shed light on the existing debate about the origin of ferromagnetism in these materials. Fe L2,3 XAS reveals that doped Fe ions are present in both Fe2+ and Fe3+ valence states. A combined theoretical and experimental study shows that doped ions are incorporated into Zn-sites of ZnO in tetrahedral symmetry. Fe L3- RIXS measurements demonstrate that a high Fe-ion dose of 8 × 107 cm-2 causes formation of FeO clusters, while low dose samples exhibit more free carriers. Mn oxides Ca-doped LaMnO3 Atomic multiplet theory X-ray absorption spectroscopy Fe-implanted ZnO
290	Characterizing Engineered Nanomaterials: From Environmental, Health and Safety Research to the Development of Shaped Nanosphere Lithography for Metamaterials Lewicka, Zuzanna 06 September 2012 (has links) In this thesis two issues in nanotechnology have been addressed. The first is the comprehensive characterization of engineered nanomaterials prior to their examination in toxicology and environmental studies. The second is the development of a method to produce nanostructure arrays over large areas and for low cost. A major challenge when assessing nanomaterial’s risks is the robust characterization of their physicochemical properties, particularly in commercial products. Such data allows the critical features for biological outcomes to be determined. This work focused on the inorganic oxides that were studied in powdered and dispersed forms as well as directly in consumer sunscreen products. The most important finding was that the commercial sunscreens that listed titania or zinc oxide as ingredients contained nanoscale materials. Cell free photochemical tests revealed that ZnO particles without any surface coating were more active at generating ROS than surface coated TiO2 nanoparticles. These studies make clear the importance of exposure studies that examine the native form of nanomaterials directly in commercial products. The second part of this thesis presents the development of a new method to fabricate gold nanoring and nanocrescent arrays over large areas; such materials have unique optical properties consonant with those described as metamaterials. A new shaped nanosphere lithography approach was used to manipulate the form of silica nanospheres packed onto a surface; the resulting array of mushroom structures provided a mask that after gold evaporation and etching left either golden rings or crescents over the surface. The structures had tunable features, with outer diameters ranging from 200 to 350 nm for rings and crescent gap angles of ten to more than a hundred degrees. The use of a double mask method ensured the uniform coverage of these structured over 1 cm2 areas. Experimental and theoretical investigations of the optical properties of the arrays revealed the optical resonances in the infrared region. Finally, in the course of developing the nanorings, etch conditions were developed to deposit large area arrays of polystyrene nanodoughnuts with diameters from 128 to 242 nm. These non-conductive structures provide an ideal template for further attachment of magnetic of optically emissive nanoparticles.

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