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1	Size-controllable growth of ZnO nanorod arrays and their surface modifications =: ZnO納米柱陣列可控生長與表面修飾. / ZnO納米柱陣列可控生長與表面修飾 / CUHK electronic theses & dissertations collection / Size-controllable growth of ZnO nanorod arrays and their surface modifications =: ZnO na mi zhu zhen lie ke kong sheng zhang yu biao mian xiu shi. / ZnO na mi zhu zhen lie ke kong sheng zhang yu biao mian xiu shi January 2010 (has links) At last, a thermal evaporation method that modifies the surface of ZnO nanorods and forms core shell structure is developed, which structure constitutes the photoelectrode for solar energy application. Single crystal ZnO nanorods are uniformly covered by wurtzite polycrystalline CdxZn1-x SySe1-y layer. The band gap of the shell can be systematically tuned from 2.5 to 1.7 eV by varying its composition, as suggested by the optical extinction measured of the samples. The type II band alignment between the ZnO core and the alloy shell enables effective photo-generated charge carrier separation, and the single crystalline ZnO nanorod array provides a direct electrical pathway for the photo-injected electron transport. The nanocable solar cells exhibited short-circuit current &sim;0.2 mA/cm 2 and open-circuit voltages of 0.45 V when illuminated with 100 mW/cm 2 simulated AM 1.5 spectrum. / Green emission is observed from the ZnO nanorods synthesized by both methods, which is commonly attributed to the surface defect emission from the nanostructure. We modify surface of the nanorods with SiO 2 and investigate the relation between green emission and the surface defect. However, the surface passivation fails to reduce the green emission significantly, suggesting that surface defects of ZnO are not necessarily responsible for the green emission, but the interior structure quality of the ZnO nanorods decides the luminescence behavior. / In this study, a solution chemistry based method to grow aligned ZnO nanorod arrays on Zn foil is developed at first. Effects of various growth parameters, including the temperature, solution composition and the concentration of individual components on the morphology, structural quality, and properties of the ZnO nanorods are studied. The average diameter of the nanorods in the array can be tuned from &sim;20 nm to &sim;150 nm by systematically changing the growth conditions. Nanorods with larger diameters are found to be of better structural quality as compared to the smaller diametered ones, as suggested by the cathodoluminescence measurement. Following similar logic, a vapor transport deposition route on controllable fabricating of the ZnO nanorod arrays is investigated. The average diameter of the ZnO nanorods can be tuned from less than 40 nm to larger than submicron, by controlling the fabrication conditions. Larger-diametered nanorods that grow on higher temperature zone are found to possess higher band edge to defect emission ratio. / One dimensional (1D) ZnO nanostructure becomes a research focus in recent years. On the one hand, ZnO itself possesses structural, electrical and optical properties that make it useful for a diverse range of technological applications. On the other hand, semiconductor nanowire owns many advantages, such as superiority in electron transport and its high surface to volume ratio. Aligned ZnO 1D nanostructures on conducting substrates are of special interests, as they are easy to be integrated into devices, directly working as functional unit. / Jiao, Yang. / Adviser: Li Quan. / Source: Dissertation Abstracts International, Volume: 72-04, Section: B, page: . / Thesis (Ph.D.)--Chinese University of Hong Kong, 2010. / Includes bibliographical references (leaves 107-109). / Electronic reproduction. Hong Kong : Chinese University of Hong Kong, [2012] System requirements: Adobe Acrobat Reader. Available via World Wide Web. / Electronic reproduction. Ann Arbor, MI : ProQuest Information and Learning Company, [200-] System requirements: Adobe Acrobat Reader. Available via World Wide Web. / Abstract also in Chinese. / Jiao, Yang. Nanostructured materials Nanotechnology Zinc oxide--Surfaces
2	Atomic structure studies of zinc oxide (0001) polar surface by low energy electron diffraction at multiple incident angles Yang, Yang, 楊暘 January 2012 (has links) Zinc oxide surfaces have been of considerable interest because of their favorable properties, such as high electron mobility, good transparency, large electronic breakdown field and wide bandgap. Knowing the surface structure of ZnO is the key to better understand the above phenomena and to further develop its applications. In this thesis, the Patterson Function was evaluated by inversion of LEED I-V spectra at multiple incident angles to determine the surface structure of the ZnO(0001) polar surface. The sample was prepared by degassing and then 15 cycles of argon sputtering and annealing. The experimental LEED I-V spectra from multiple incident angles were taken from the sample. After processing the data by a macro program in OPTIMAS and a Matlab program, a clean Patterson Function map showing the inter-atomic pair distances was obtained. It was then compared with the simulated Patterson Function map of the proposed 1×1 bare surface model. As a result, the spots positions in the simulated Patterson Function map matched well with that of the experimental Patterson Function map. On the other hand, the LEED I-V curve fitting work was done by the surface science group of City University of Hong Kong. Six models were proposed by them and normal incidence theoretical LEED I-V spectra were calculated to fit with the experimental LEED I-V curves provided by us. Among the six models 2×2 Zn point defect model was fitted to be the best model with the R-factor 0.244. We also compared the multiple scattering simulated Patterson Function map of 2×2 Zn point defect model with the experimental one to verify the validity of the model. As a result, the model fit the experimental data. So we conclude that in general 1×1 model support the order part, and 2×2 top layer Zn defect model best fits the random missing part. / published_or_final_version / Physics / Master / Master of Philosophy Zinc oxide - Surfaces. Low energy electron diffraction.
3	Scanning Tunneling Microscopy and Adsorption Studies on Single-Crystal Metal Oxide Surfaces Conway, Timothy James 05 September 1997 (has links) Natural and synthetic SnO₂ samples were studied using scanning tunneling microscopy (STM). The SnO₂ surface flattens considerably following high temperature treatments up to 1500 K. The conductivity of the synthetic SnO₂ surface is significantly reduced following annealing at temperatures of approximately 1200-1500 K, making tunneling impossible. A decrease in conductivity was not observed for the natural SnO₂ sample following similar high temperature treatments, most likely due to impurities which act as dopants. No atomic scale images were collected on the SnO₂ surface which provided information regarding atomic positions and point defects on the surface. Water adsorption was studied on the stoichiometric Cr₂O₃ (101̲2) surface, using thermal desorption spectroscopy (TDS). Water was the only desorption product observed during TDS. Adsorption is primarily dissociative following exposure to water at 163 K. Approximately, 0.12 monolayers of water dissociate on the clean, nearly stoichiometric Cr₂O₃ (101̲2) surface. The first order kinetics observed for the recombination of dissociated water are not well understood. One possible explanation is that the rate limiting step for desorption involves the breaking of a Cr-O bond resulting in a freely diffusing OH species. The exchange of halogen and oxygen was studied on Cr₂O₃ (101̲2) using Auger electron spectroscopy (AES) and TDS. The exchange of chlorine and oxygen is completely reversible. Chlorine is removed from the Cr₂O₃ (101̲2) surface following exposure to oxygen. Exposure of CFCl₂CH₂Cl reduces the surface oxygen concentration to that of the clean, nearly stoichiometric Cr₂O₃ (101̲2) surface. The exchange of chlorine with oxygen appears to involve only chemisorbed surface oxygen, not bulk lattice oxygen. / Master of Science metal oxide surfaces scanning tunneling microscopy
4	Structure determinations of SnO₂ and TiO₂ surfaces by low energy electron diffraction Patterson inversion method Leung, Wai-yan., 梁偉恩. January 2013 (has links) The Tin dioxide (SnO2) and Titanium dioxide (TiO2) are very promising materials in Material science. The SnO2 is commonly used as a gas sensor while the TiO2 is used as a catalyst in many reactions. Despite of the usefulness of these two substances, their surface structures lack detail investigations in the previous years. The Low Energy Electron Diffraction (LEED) technique is commonly used to characterize surfaces in the past 40 years, it is a mature system that many researches rely on its result. However, structural analysis in LEED requires comparison with computational results based on pre-defined structure models, which is a time-consuming method and the results are not guaranteed to be found. The direct determinations of structure by Patterson function inversion methods introduced by Huasheng Wu and S. Y. Tong could provide a different path to search for surface structure. In the Patterson function, each maximum in the function corresponds to a relative position vector of atomic pairs. Multiple-angle-incident LEED has to be performed to obtain an artifact-free Patterson function. Serveal SnO2 and TiO2 surfaces have been characterized by LEED and Patterson function inversion. SnO2 (110), (100), (101) , Rutile TiO2 (110), Anatase TiO2 (110) have been prepared by argon ion sputtering and annealing cycles and the cleanness has been checked by Auger Electron Spectroscopy and LEED. Reconstruction is observed based on the study of the LEED patterns. SnO2 (110) surface shows a 4 x 1 reconstruction in UHV environment while it gives 1 x 1 under annealing in oxygen and C(2 x 2) at higher annealing temperature afterward. SnO2 (100) , (101) and Rutile TiO2 (110) surfaces show 1 x 1 reconstruction in UHV environment and the reconstruction persists for further annealing. The Anatase TiO2 (110) surface shows a 3 x 4 reconstruction in UHV environment. The 3 x 4 reconstruction of Anatase TiO2 (110) surface would raise research interests as it is quite a special reconstruction. Multiple-angle-incident LEED has been performed on the SnO2 (100), (101) and Rutile TiO2 (110) surfaces. Patterson function inversion is performed on the surfaces SnO2 (100) and Rutile TiO2 (110) . Only LEED is performed on SnO2 (110) , (101) and Anatase TiO2 (110) surfaces. From Patterson functions analysis, the surface atoms positions are determined for the surface SnO2 (100) and Rutile TiO2 (110). The results show that their reconstructions are negligible, but they have obvious relaxations. / published_or_final_version / Physics / Master / Master of Philosophy Low energy electron diffraction. Patterson function. Stannic oxide - Surfaces. Titanium dioxide - Surfaces.
5	Determination of surface atomic structures of Bi₂Se₃(111)-(2X2) film and ZnO nano-rods by low energy electron diffraction Chung, Wing-lun, 鍾詠麟 January 2014 (has links) abstract / Physics / Doctoral / Doctor of Philosophy Atomic structure Low energy electron diffraction Zinc oxide - Surfaces Bismuth compounds - Surfaces
6	Growth and structure of an ultrathin tin oxide film on Rh (111) Varga, P., Schmid, M., Muto, S., Tatsumi, K., Matsui, T., Tajima, D., Yuhara, J. 01 1900 (has links) No description available. Surface structure Scanning tunneling microscopy Oxide surfaces Thin film structure Tin
7	Sulfur-induced Corrosion at Metal and Oxide Surfaces and Interfaces Cabibil, Hyacinth (Hyacinth Liesl) 08 1900 (has links) Sulfur adsorbed on metallic and oxide surfaces, whether originating from gaseous environments or segregating as an impurity to metallic interfaces, is linked to the deterioration of alloy performance. This research dealt with investigations on the interactions between sulfur and iron or iron alloy metallic and oxide surfaces under ultrahigh vacuum conditions. Sulfur was either intentionally dosed from a H2S source on an atomically clean metal surface, or segregated out as an impurity from the bulk to the metal surface by annealing at elevated temperatures. sulfur-induced corrosion metal surfaces oxide surfaces Alloys -- Corrosion. Corrosion and anti-corrosives. Metallic oxides -- Surfaces. Sulfur.
8	AFM force spectroscopies of surfaces and supported plasmonic nanoparticules / Spectroscopie et microscopie à force atomique sur des surfaces et nanoparticules plasmoniques Craciun, Andra 15 March 2017 (has links) Dans ce travail de thèse, le microscope à force atomique (AFM) a été utilisé comme outil de manipulation de haute précision pour construire des nanostructures plasmoniques avec des géométries définies et un réglage précis de la distance interparticulaire et également comme technique de spectroscopie d'absorption. Différentes études concernant les phénomènes pertinents pour la manipulation des nanoparticules et émergeant à l'interface substrat-nanoparticules, ont été réalisées. Des expériences de frottement menées sur diverses surfaces d'oxydes ont révélé un nouveau mécanisme de frottement à l’échelle nanométrique, expliqué par un modèle de potentiel d'interaction de type Lennard-Jones modifié. Les propriétés de frottement et d'adhésion de CTAB adsorbé sur silice sont également présentées. Des nano-bâtonnets d'or fonctionnalisés par du CTAB ont été manipulés par AFM afin de construire des nanostructures plasmoniques. La dernière partie de la thèse présente les efforts expérimentaux et théoriques pour démontrer la faisabilité de l'utilisation d'un AFM comme une technique de spectroscopie optoélectronique à base de force. / In this thesis work the atomic force microscope (AFM) was employed first as a high precision manipulation tool for building plasmonic nanostructures with defined geometries and precise tuning of interparticle distance and second as an absorption spectroscopy technique. Different studies regarding phenomena emerging at sample nanoparticle interface relevant for nanoparticle manipulation were performed. Friction experiments conducted on various oxide surfaces revealed a novel nanoscale stick slip friction mechanism, explained by a modified Lennard-Jones-like interaction potential model. Frictional and adhesion properties of CTAB adsorbed on silica are also reported. CTAB functionalized gold nanorods were used for building specific plasmonic particulate nanostructures. The final part of the thesis presents experimental and theoretical efforts to demonstrate the feasibility of using an AFM as a force-based optoelectronic spectroscopy technique. Microscopie à force atomique Nanoparticules plasmoniques Nano-bâtonnets d'or AFM nanomanipulation Atomic force microscopy Plasmonic nanoparticles Nanoscale stick-slip friction Gold nanorods AFM nanomanipulation CTAB adsorption on oxide surfaces 621 620.5
9	Molecular dynamics simulations of amine-based friction modifiers : diffusion, adsorption and friction behaviors / Simulation en dynamique moléculaire des modificateurs de frottement aminés : comportement en diffusion, adsorption et frottement Pereira De Matos, Rafael 19 April 2019 (has links) Les amines grasses sont présentes dans la formulation de lubrifiants automobiles, en tant que modificateurs de frottement organiques (MFO), afin d'atténuer les effets négatifs entraînés par le frottement et l'usure induits au sein des pièces sujettes aux conditions limites (c'est-à-dire, sous haute pression et basse vitesse de glissement). Outre leurs propriétés de lubrification, ces additifs présentent l'avantage d'être compatibles avec les systèmes de dépollution des gaz d'échappement, puisque leur composition organique est exempte d'éléments nocifs, tels que le soufre, le phosphore et certains métaux. Ainsi, un protocole de calcul en dynamique moléculaire classique a été mis en place et utilisé pour étudier, à l'échelle moléculaire, les propriétés des surfactants. En particulier, trois mécanismes d'action ont été considérés, à savoir : leur diffusion dans un milieu liquide, leur adsorption sur des substrats solides, et leur comportement en frottement. Dans ce contexte, différents facteurs associés à la structure des constituants des lubrifiants ont été analysés, notamment leur effet sur la performance des MFO. Les simulations révèlent que : (i) Diffusion – le coefficient de diffusion des composés aminés sont considérablement impactées par les caractéristiques de l'huile de base (exemple: leur polarité et masse moléculaire), sachant que les modèles de solvant les plus polaires et les plus lourds provoquent le ralentissement du flux diffusif des MFO ; par ailleurs, la structure des additifs jouent également un rôle dans leur diffusion, où les molécules les plus petites et les moins polaires s'avèrent relativement les plus mobiles. (ii) Adsorption – les amines primaires réagissent chimiquement avec une surface d'oxyde de fer, en formant des monocouches auto-assemblées, dont l'organisation et l'épaisseur augmentent avec leur taux de recouvrement. (iii) Frottement – les films adsorbés contenant d'amines constituées d'une chaîne hydrocarbonée C18 linéaire et saturée sont capables de réduire le frottement d'un système modèle représentant un nano-contact en régime limite ; en plus, leur efficacité dépend de la microstructure développée par les amines adsorbées sur les substrats sous compression et cisaillement ; d'ailleurs, les films permettant la formation de(s) plan(s) de glissement bien défini(s) entre les molécules organiques confinées sont davantage disposés à diminuer la résistance de glissement. Par conséquent, ces études ont permis de confirmer l'intérêt de l'apport d'une approche numérique complémentaire aux techniques expérimentales dans le but de comprendre les phénomènes élémentaires des systèmes tribologiques. / Fatty amines and their derivatives are employed as organic friction modifiers (OFM) in lubricant oils in order to mitigate the negative effects of friction and wear, both induced by the moving and rubbing components of an internal combustion engine that are subjected to boundary lubrication conditions (i.e., high contact pressure and low sliding velocity). In addition to their tribological performance, these additives exhibit the benefit of being compatible with exhaust aftertreatment systems that equip the current light-duty vehicles, owing to their sulfur- and phosphorus-free chemical composition. For these reasons, we have developed a computational protocol, composed of equilibrium and non-equilibrium (classical) molecular dynamics simulations, in order to gain a deeper understanding into their mechanisms of action at nanoscale, and in particular into their diffusion, adsorption and friction behaviors. In this context, the influence of different molecular structure factors – related to lubricant constituents – on OFM working performance were investigated. The obtained results have shown that: (i) Diffusion – OFM diffusivity is substantially affected by the base oil structure and chemistry (e.g., polarity and molar mass), where solvents with relatively larger and higher polar groups tend to slow down their diffusive rate; besides, the OFM dynamics in liquid phase is also impacted by their own composition, being the molecules with relatively smaller and less polar structure the most mobile additives. (ii) Adsorption – primary alkyl amines do chemisorb onto iron-oxide substrates, thereby forming molecular films whose packing order and thickness increase with increasing surface coverage. (iii) Friction – adsorbed layers containing primary amines with linear, saturated, C18 hydrocarbon tails are able to reduce friction in a single-asperity, boundary nano-contact model, where their efficiency is dependent on their molecular ordering under confinement and shear; in addition, the organic films allowing the formation of well-defined slippage interface(s) with little molecular interdigitation are more prone to diminish the sliding resistance of solid substrates in relative motion.Therefore, those findings are expected to foster the exploration and development of computational simulation approaches, as a complement of experimental techniques, to investigate the fundamental phenomena present in tribological-relevant engineering systems. Modificateurs de frottement organiques Amines Surfaces d’oxyde de fer Dynamique moléculaire Diffusion Adsorption Frottement Organic friction modifiers Fatty amines Iron oxide surfaces Boundary lubrication regime Classical molecular dynamics Diffusion Adsorption Friction
10	Interaction of Water with the Fe2O3(0001) Surface Ovcharenko, Roman 29 June 2018 (has links) Diese Arbeit ist eine umfassende und systematische Untersuchung der Adsorption von Wasser auf der Fe2O3(0001)-Oberfläche. Sie deckt eine Vielzahl der Probleme auf, die während des Anfangs der Wasseradsorption auf den Übergangsmetalloxidoberflächen auftreten. Dazu gehören die Stabilität der reinen Oberfläche, die Rolle der Oberflächendefekte, der Einfluss der kristallographischen und elektronischen Strukturen, die elementare Kinetik der adsorbierten Arten von Wasser auf der Oberfläche, die Eigenschaften bei niedrigem und hohem Bedeckungsgrad und die Auswirkungen der Wasserstoffbrückenbindung auf die Adsorption und das XPS-Spektrum. Niedrige und hohe Bedeckungsgrade von 0.25 bis 1 Monolage werden untersucht, um die Grundlage für die folgende Erhöhung der Wasserbedeckung, die normalerweise in Experimenten beobachtet wird, zu ermitteln. Das Einzeladsorptionsregime wurde erweitert, um eine echte Wasserdampfumgebung mittels der Gibbs-Energie zu berücksichtigen. Die Ensemblemethode wurde benutzt, um die durchschnittlichen Werte der energisch entarteten Adsorptionskonfigurationen zu interpretieren. Der Abstandsmatrixansatz wurde entwickelt, um die statistische Analyse zu ermöglichen. Die Methode reduziert mithilfe der Oberflächensymmetrie die Gesamtzahl der Adsorptionskonfigurationen, die zu berücksichtigen sind. Das XPS-Spektrum wird für verschiedene Wasserdampftemperaturen und Drücke simuliert. Es wird eine gute Übereinstimmung zwischen theoretischen und experimentellen Spektren erreicht und die geringen Unterschiede werden erklärt. Die Hauptmerkmale des XPS-Spektrums beim Anstieg von relativer Feuchtigkeit des Wasserdampfs werden beschrieben. Die Ähnlichkeiten und Unterschiede der Wasseradsorption auf Fe2O3 und Al2O3 werden betont und die wichtigsten Tendenzen werden abgeleitet. Auf Grund dieser Arbeit kann der Anfangsprozess der Fe2O3(0001)-Oberflächenbenetzung erklärt werden. / The present study is a comprehensive systematic theoretical investigation of the water adsorption on the Fe2O3(0001) surface. It covers a broad number of problems inherent to the initial stage of the water adsorption on the transition metal oxide surface: clean surface stability, the influence of surface oxygen defects, the role of the crystallographic and electronic structures on the adsorption configuration, elementary kinetics, the particular qualities of the low and high adsorption coverage regimes and the effect of the hydrogen bonding on adsorption and on the XPS spectra simulation. The low and high coverage regimes from 0.25 up to 1 monolayer water coverage were considered to form a basis for the following increase of water loading mainly observed in experiments. A single adsorption energy picture was expanded to take into account the water vapour environment through the Gibbs free energy. The statistical ensemble was employed to classify and interpret the averaged values of the adsorption configurations set rather than the ``invisible'' in experiment quantities intrinsic to the particular single adsorption configuration. In order to make the statistical analysis feasible an effective distance matrix scheme was developed. It helped to reduce the total number of structures to consider without loss of generality by virtue of the surface space symmetry. Based on the statistical contribution of each individual adsorption configuration, the O-1s XPS was simulated for the various water vapour environments. A good agreement between the simulated and experimental spectra was found. Wherever it was important, the similarities and differences between water adsorption on the Fe2O3, Al2O3 and Fe3O4 surfaces were stressed and the main tendencies were deduced. Based on the present study, the whole picture of the initial stage of the Fe2O3(0001) surface wetting process was established. H2O/Fe2O3(0001) Stabilität der Hämatit-Oberfläche Simulation der XPS-Spektren H2O/Fe2O3(0001) stability of the hematite terminations simulation of XPS spectra 541 Physikalische Chemie 539 Moderne Physik VE 5657 VC 6107 VE 7007 ddc:541 ddc:540 ddc:539

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