Global ETD Search

11	Electrochemical Deposition of Nanostructured Metal/Metal-Oxide Coatings Eskhult, Jonas January 2007 (has links) <p>Electrochemical deposition finds applications in the electronics- and protective coating industries. The technique is a versatile tool for the synthesis of alloys and thin films. Knowledge of the fundamental aspects of the electrode processes enables the design of nanostructured materials. In this thesis, electrodeposition processes in solutions containing metal ion complexes were studied and new methods for the preparation of metal/metal-oxide coatings were developed and evaluated. </p><p>Metal/metal oxide coatings were electrodeposited from aqueous solutions containing metal complexes of hydroxycarboxylic acids under reducing conditions. The mass changes of the working electrode were monitored <i>in-situ</i> with the electrochemical quartz crystal microbalance (EQCM) technique and ellipsometry was used to detect the formation of Cu<sub>2</sub>O. The coatings were further characterized with XRD, XPS, SEM, TEM, and Raman spectroscopy. Electrochemical methods, including reduction of Sb/Sb<sub>2</sub>O<sub>3</sub> in an organic electrolyte, were also used to study the properties of the deposited materials. </p><p>Nanostructured coatings of Cu/Cu<sub>2</sub>O were obtained during spontaneous potential or current oscillations in alkaline Cu(II)-citrate solutions. The oscillations were due to local pH variations induced by a subsequent chemical step and comproportionation between Cu and Cu<sup>2+</sup>. Well-defined layers of Cu and Cu<sub>2</sub>O could be prepared by a galvanostatic pulsing technique, allowing independently controlled thickness of several hundred nanometers. Coatings, containing Sb and co-deposited, nanograins of Sb<sub>2</sub>O<sub>3,</sub> with a thickness of up to 200 nm were prepared from poorly buffered Sb(III)-tartrate solutions. Galvanostatic cycling showed that the latter material could be reversibly charged and discharged in a Li-ion battery for more than 50 cycles with a capacity of 660 mAh/g. </p><p>The results show that precipitations of metal oxides can occur due to local pH increases during electrochemical deposition from metal complexes with ligands containing hydroxyl groups. The ability to deposit metal oxides using cathodic deposition relies on a sufficiently slow reduction of the oxide. </p> Inorganic chemistry electrochemical deposition local pH Cu2O Sb2O3 complex EQCM reduction Oorganisk kemi
12	Etude expérimentale et modélisation de l'oxydation sèche d'une poudre de nanoparticules de cuivre Mansour, Mounir 03 July 2013 (has links) (PDF) Une étude de l'oxydation d'une poudre de nanoparticules de cuivre a été menée à 120 - 145°C sous des pressions partielles d'oxygène allant de 1 à 40 kPa. La réaction a été suivie par thermogravimétrie afin d'obtenir les données cinétiques. Des caractérisations chimiques, texturales et morphologiques de la poudre ont été réalisées à différents moments de la transformation. La cuprite (Cu2O) (produit unique) de la réaction croît d'une manière anisotrope et par développement externe autour de la particule initiale qui devient creuse. Une diminution de la surface spécifique et de la porosité de la poudre au cours de la transformation a été mise en évidence.Des tests cinétiques ont montré l'existence d'une étape limitante de croissance jusqu'à un taux de conversion de 0,7 à 140°C. Il a également été montré que pour P(O2) ≤ 4 kPa, les processus de germination et de croissance de l'oxyde interviennent simultanément pendant la réaction et que l'adsorption de l'oxygène est l'étape limitante. Pour P(O2) ≥ 20 kPa, la germination se fait instantanément au début de la transformation dont la vitesse est contrôlée par le processus de croissance, la diffusion du cuivre étant alors l'étape limitante. Deux modèles ont été construits et testés avec succès pour décrire la cinétique dans les deux gammes de P(O2) jusqu'à un taux de conversion donné. Pour expliquer le ralentissement observé au-delà de ce taux de conversion et pour P(O2) ≤ 4 kPa, le modèle a été couplé aux phénomènes de transfert de chaleur et de matière au sein des agglomérats. Ce couplage permet d'évaluer l'hypothèse d'un ralentissement de la réaction par la diffusion des molécules d'oxygène dans les pores de l'agglomérat. [SPI:OTHER] Engineering Sciences/Other Cuprite Cu2O Germination-croissance Thermogravimétrie Transfert de chaleur Pseudo-stationnarité Nanoparticules Mécanisme réactionnel
13	Computational Study Of Ethylene Epoxidation Ozbek, Murat Olus 01 October 2011 (has links) (PDF) This work computationally investigates the partial oxidation of ethylene (i.e. ethylene epoxidation) using periodic Density Functional Theory (DFT) on slab models that represent the catalyst surfaces. The mechanical aspects of the reaction were investigated on silver surfaces, which are industrially applied catalysts, for a wide range of surface models varying from metallic surfaces with low oxygen coverage to oxide surfaces. For comparison, the metallic and oxide phases of copper and gold were also studied. On these surfaces, the reaction paths and the transition states along these paths for the selective and non-selective reaction channels were obtained using the climbing image nudged elastic band (CI-NEB) method. In order to answer the question &ldquo / what is the relation between the surface state and the ethylene oxide selectivity?&rdquo / metallic (100), (110) and (111) surfaces of Cu, Ag and Au / and, (001) surfaces of Cu2O, Ag2O and Au2O oxides were studied and compared. For the studied metallic surfaces, it was found that the selective and non-selective reaction channels proceed through the oxametallacycle (OMC) intermediate, and the product selectivity depends on the relative barriers of the these channels, in agreement with the previous reports. However for the studied metallic surfaces and oxygen coverages, a surface state that favors the ethylene oxide (EO) formation was not identified. The studied Au surfaces did not favor the oxygen adsorption and dissociation, and the Cu surfaces favored the non-selective product (acetaldehyde, AA) formation. Nevertheless, the results of Ag surfaces are in agreement with the ~50% EO selectivity of the un-promoted silver catalyst. The catalyst surface in the oxide state was modeled by the (001) surfaces of the well defined Cu2O, Ag2O and Au2O oxide phases. Among these three oxides, the Cu2O is found not to favor EO formation whereas Au2O is known to be unstable, however selective for epoxidation. The major finding of this work is the identification of a direct epoxidation path that is enabled by the reaction of the surface oxygen atoms, which are in two-fold (i.e. bridge) positions and naturally exist on (001) oxide surfaces of the studied metals. Among the three oxides studied, only Ag2O(001) surface does not show a barrier for the formation of adsorbed epoxide along the direct epoxidation path. Moreover, the overall heat of reaction that is around 105 kJ/mol agrees well with the previous reports. The single step, direct epoxidation path is a key step in explaining the high EO selectivities observed. Also for the oxide surfaces, the un-selective reaction that ends up in combustion products is found to proceed through the OMC mechanism where aldehyde formation is favored. Another major finding of this study is that, for the studied oxide surfaces two different types of OMC intermediates are possible. The first possibility is the formation of the OMC intermediate on oxygen vacant sites, where the ethylene can interact with the surface metal atoms directly. The second possibility is the formation of a direct OMC intermediate, through the interaction of the gas phase ethylene with the non-vacant oxide surface. This occurs through the local surface reconstruction induced by the ethylene. The effect of Cl promotion was also studied. Coadsorption of Cl is found to suppress the oxygen vacant sites and also the reconstruction effects that are induced by ethylene adsorption. Thus, by preventing the interaction of the ethylene directly with the surface metal atoms, Cl prevents the OMC formation, therefore the non-selective channel. At the same time Cl increases the electrophilicity of reacting surface oxygen. The direct epoxidation path appears to be stabilized by coadsorbed oxygen atoms. Thus, we carry the discussions on the silver catalyzed ethylene epoxidation one step further. Herein we present that the EO selectivity will be limited in the case of metallic catalyst, whereas, the oxide surfaces enable a direct mechanism where EO is produced selectively. The role of the Cl promoter is found to be mainly steric where it blocks the sites of non-selective channel. QD Quantum Chemistry 462
14	Electrochemical Deposition of Nanostructured Metal/Metal-Oxide Coatings Eskhult, Jonas January 2007 (has links) Electrochemical deposition finds applications in the electronics- and protective coating industries. The technique is a versatile tool for the synthesis of alloys and thin films. Knowledge of the fundamental aspects of the electrode processes enables the design of nanostructured materials. In this thesis, electrodeposition processes in solutions containing metal ion complexes were studied and new methods for the preparation of metal/metal-oxide coatings were developed and evaluated. Metal/metal oxide coatings were electrodeposited from aqueous solutions containing metal complexes of hydroxycarboxylic acids under reducing conditions. The mass changes of the working electrode were monitored in-situ with the electrochemical quartz crystal microbalance (EQCM) technique and ellipsometry was used to detect the formation of Cu2O. The coatings were further characterized with XRD, XPS, SEM, TEM, and Raman spectroscopy. Electrochemical methods, including reduction of Sb/Sb2O3 in an organic electrolyte, were also used to study the properties of the deposited materials. Nanostructured coatings of Cu/Cu2O were obtained during spontaneous potential or current oscillations in alkaline Cu(II)-citrate solutions. The oscillations were due to local pH variations induced by a subsequent chemical step and comproportionation between Cu and Cu2+. Well-defined layers of Cu and Cu2O could be prepared by a galvanostatic pulsing technique, allowing independently controlled thickness of several hundred nanometers. Coatings, containing Sb and co-deposited, nanograins of Sb2O3, with a thickness of up to 200 nm were prepared from poorly buffered Sb(III)-tartrate solutions. Galvanostatic cycling showed that the latter material could be reversibly charged and discharged in a Li-ion battery for more than 50 cycles with a capacity of 660 mAh/g. The results show that precipitations of metal oxides can occur due to local pH increases during electrochemical deposition from metal complexes with ligands containing hydroxyl groups. The ability to deposit metal oxides using cathodic deposition relies on a sufficiently slow reduction of the oxide. Inorganic chemistry electrochemical deposition local pH Cu2O Sb2O3 complex EQCM reduction Oorganisk kemi
15	In-situ XPS Investigation of the Surface Chemistry of a Cu(I) Beta-Diketonate Precursor and the ALD of Cu2O Dhakal, Dileep, Waechtler, Thomas, E. Schulz, Stefan, Mothes, Robert, Lang, Heinrich, Gessner, Thomas 07 July 2014 (has links) (PDF) This poster was presented in the Materials for Advanced Metallization (MAM) 2014 Conference in Chemnitz, Germany. Abstract: Atomic Layer Deposition (ALD) has emerged as an ubiquitous method for the deposition of conformal and homogeneous ultra-thin films on complex topographies and large substrates in microelectronics. Electrochemical deposition (ECD) is the first choice for the deposition of copper (Cu) into the trenches and vias of the interconnect system for ULSI circuits. The ECD of Cu necessitates an electrically conductive seed layer for filling the interconnect structures. ALD is now considered as a solution for conformal deposition of Cu seed layers on very high aspect ratio (AR) structures also for technology nodes below 20 nm, since physical vapor deposition is not applicable for structures with high AR. Cu seed layer deposition by the reduction of Cu2O, which has been deposited from the Cu(I) β-diketonate precursor [(nBu3P)2Cu(acac)], has been successfully carried out on different substrates like Ta, TaN, SiO2, and Ru [1, 2]. However, still many questions are unanswered regarding the underlying surface chemistry of the precursor on many substrates, leading to different growth modes during ALD. In this work, the surface chemistry of [(nBu3P)2Cu(acac)] on SiO2 substrate is investigated by in-situ X-ray photoelectron spectroscopy (XPS), reporting vital information about the oxidation state and the atomic concentration after chemisorption on the substrates kept at different temperatures. The aim of the investigation is to understand the stepwise change in the precursor oxidation state with increasing substrate temperature and to identify the temperature limit for the thermal ALD with this Cu precursor on SiO2. For the experiments, the Cu precursor was evaporated on SiO2 substrates kept at temperatures between 22 °C and 300 °C. The measured C/Cu and P/Cu concentration indicated that most of the nBu3P ligands were released either in the gas phase or during adsorption (Fig. 1a). No disproportionation was observed for the Cu precursor in the temperature range between 22 °C and 145 °C. Similarly, in this temperature range the Auger parameter calculated from Cu 2p3/2 and Cu L3VV spectra was found to be 360.0±0.2 eV, comparable to Cu(I) oxidation state [3]. However, disproportionation of the Cu precursor was observed above 200 °C, since C/Cu concentration ratio decreased and substantial metallic Cu was present on the substrate. Hence, 145 °C is the temperature limit for the ALD of Cu2O from this precursor, as the precursor must not alter its chemical state after chemisorption on the substrate. 500 ALD cycles with the probed Cu precursor and wet O2 as co reactant were carried out on SiO2 at 145 °C. After ALD, in situ XPS analysis confirmed the presence of Cu2O on the substrate. Ex-situ spectroscopic ellipsometry indicated an average film thickness of 2.5 nm of Cu2O deposited with a growth per cycle of 0.05 Å/cycle, comparable to previous experiments. References: [1] T. Waechtler, S. Oswald, N. Roth, A. Jakob, H. Lang, R. Ecke, S. E. Schulz, T. Gessner, A. Moskvinova, S. Schulze, M. Hietschold, J. Electrochem. Soc., 156 (6), H453 (2009). [2] T. Waechtler, S. -F. Ding, L. Hofmann, R. Mothes, Q. Xie, S. Oswald, C. Detavernier, S. E. Schulz, X. -P. Qu, H. Lang, T. Gessner, Microelectron. Eng., 88, 684 (2011). [3] J. P. Espinós, J. Morales, A. Barranco, A. Caballero, J. P. Holgado, A. R. González Elipe, J. Phys. Chem. B, 106, 6921 (2002). Kupferoxide In-situ XPS Atomic Layer Depositon (ALD) Copper Oxide (Cu2O) ddc:620 ddc:530 Kupferoxide
16	Effets de taille et de concentration sur les propriétés thermiques et rhéologiques des nanofluides Hadaoui, Abdellah 16 December 2010 (has links) (PDF) Le travail présenté dans cette thèse porte sur la synthèse et les caractérisations thermiques et rhéologiques d'un nouveau type de nanofluide : le système Cu2O/Glycérol. La caractérisation est faite en fonction de la taille des particules mises en suspension, de la température et de la fraction volumique solide. Ce travail a nécessité la synthèse des nanoparticules et des nanofluides par la méthode de décomposition thermique des précuseurs organométalliques, qui présente un bon rendement en quantité de nanoparticules (17%). Et le montage d'un dispositif de caractérisation thermique utilisant la méthode 3ω. Finalement, nous avons passé à la caractérisation rhéologique et thermique de ces échantillons. Les résultats obtenus avec ce nouveau système sont intéressants, car l'augmentation de la conductivité thermique atteint des valeurs importantes : 120% et 35% respectivement pour des fractions volumiques aussi faibles que 0,625% et 0,078% de nanoparticules de 7 nm de diamètre, sans influence notable sur la viscosité du fluide hôte, permettant une bonne amélioration du bilan énergétique total. Nous avons observé que la concentration et la taille (surface) des nanoparticules sont des paramètres clefs du comportement de la conductivité thermique effective du nanofluide Cu2O/Glycérol. Nos mesures nous ont permis de déduire la prédominance des modifications de la surface des nanoparticules (par fonctionnalisation ou par réaction chimique secondaire) sur le mouvement brownien dans les transferts thermiques nanoparticules/ fluide hôte. [SPI:OTHER] Engineering Sciences/Other Système Cu2O/Glycérol Conductivité thermique Méthode 3ω
17	Localization dynamics of paraexcitons and their lattice relaxation at oxygen vacancies in cuprous oxide / 亜酸化銅パラ励起子の酸素欠陥への局在化のダイナミクスと格子緩和の研究 Sandhaya Koirala 23 July 2014 (has links) 京都大学 / 0048 / 新制・課程博士 / 博士(理学) / 甲第18494号 / 理博第4009号 / 新制\|\|理\|\|1578(附属図書館) / 31380 / 京都大学大学院理学研究科物理学・宇宙物理学専攻 / (主査)准教授中暢子, 教授田中耕一郎, 教授金光義彦 / 学位規則第4条第1項該当 / Doctor of Science / Kyoto University / DGAM paraexciton in Cu2O time-resolved photoluminescence defect center adiabatic potential model 400
18	Nanoscale electrical properties of heterojunction interfaces for solar cells : modeling and experiments Eriksson, Martin January 2018 (has links) A numerical model have been developed in order to describe and achieve deeper understanding of experimentally obtained I-V curves from Cu2O/ZnO p-n heterojunctions for potential use as future solar cell material. The model was created using the simulation software COMSOL Multiphysics® and their semiconductor module. To experimentally study the samples two approaches were taken: (1) macro-electrical measurements and (2) local I-V measurements using conductive AFM. The final model is one-dimensional, time dependent and with the ability to study photovoltaic effects of samples with different layer thickness at different voltage ramping speeds and different light irradiance. The model is also able to study the effects of using different contact materials by treating the contacts as ideal Schottky contacts. The dynamic behavior of a Cu_2O/ZnO heterojunction was studied by considering the systems response to a voltage step and the effect of changing the voltage ramping speed. The output from the step response, the current as a function of time, is varying a short time after a step has occurred before settling on to a steady value. The response also shows an overshoot of the current in the direction of the voltage step and the final steady value depends on whether the junction is conducting or not. The effects of this behavior on the shape of the I-V curves are witnessed when studying the different voltage ramping speeds. The voltage is ramped from 2 V to -2 V and back again for different speeds (V/s). The I-V curves have different shapes when sweeping the voltage in different directions and the magnitude increases with increasing speed. The photovoltaic effects were studied by applying different light irradiances. The behavior of the model agrees well with the theory for an ideal diode solar cell. An investigation was done of how the work function of the metal in contact with the Cu_2O affects the shape of the I-V curve under dark and illuminated conditions. The metal work function was changed from 4.5 eV to 6.5 eV in steps of 0.4 eV and does not affect the shape of the I-V curves much in dark after increasing it above 4.5 eV. The effects are more visible under illuminated conditions where a "step"-behavior appears for the lower values of the work function. Only one of the physical samples show a noticeable light effect. The macro-electrical measurement on this sample is compared with simulated results and are in qualitative agreement with each other. The agreement between the local electrical measurements and the simulated results is not as good with the current model. solar cell heterojunction ZnO Cu2O Comsol atomic force microscopy I-V characteristics Physical Sciences Fysik
19	Photoluminescence and Extended X-ray Absorption Fine Structure Studies on CdTe Material Liu, Xiangxin 20 June 2006 (has links) No description available. Physics, Condensed Matter Photovoltaics CdTe CdCl2 treatement Ion Implantation Photoluminescence EXAFS Cu2O
20	Synthesis and applications of multifunctional hybrid materials based on microgel particles Jia, He 02 December 2016 (has links) Die Kombination aus anorganischen Nanopartikeln und Mikrogelen in einem hybriden System erlaubt die Herstellung von Materialien mit vielseitigen neuen Eigenschaften. Im Idealfall weisen solche hybriden Materialien neben den Eigenschaften von beiden indivduellen Systemen zusätzlich synergetische Effekte auf, welche aus den Interaktionen zwischen dem anorganischen Nanopartikel und dem Mikrogel resultieren. Im ersten Teil dieser Arbeit wird eine neuartige und eingängige Methode zur Herstellung von Cu2O@PNIPAM Kern-Schale Nanoreaktoren präsentiert. Die PNIPAM Schale schützt dabei die Cu2O Nanopartikel effektiv vor Oxidation. Die Cu2O@PNIPAM wurden als Photokatalysator zum Abbau von Methylorange unter sichtbarem Licht eingesetzt. Im Vergleich zu den reinen Cu2O Nanopartikeln konnte eine signifikante Steigerung der katalytischen Aktivität festgestellt werden. Desweiteren kann die photokatalytische Aktivität mittels Temperatur durch die thermosensitive PNIPAM Schale abgestimmt werden. Verhältnismäßig geringe Konzentrationen einer Cu2O@PNIPAM wässrigen Lösung (1,5 Gew%) können direkt als neuartige Tinte genutzt werden. Keine zusätzlichen Additive oder organische Lösungsmittel sind für die Strahldruckprozesse vonnöten. Gedruckte Bauelemente bestehend aus den Cu2O@PNIPAM wurden als Gas Sensoren eingesetzt und zeigten eine geringere Nachweisgrenze für NO2 als die reinen Cu2O Nanowürfel. Im zweiten Teil der Arbeit wurden katalytisch aktive Au Nanopartikel an copolymerisierten α –Cyclodextrin (α-CD) Einheiten in einem Poly(N-vinylcaprolactan) (PVCL) Mikrogel immobilisiert. Diese hybriden Partikel sind sehr aktive Katalysatoren für die Reduktion von aromatischen Nitroverbindungen. Die Reduktion von 4-Nitrophenol (Nip) und 2,6-Dimethyl-4-nitrophenol (DMNip) wurden als Modellreaktionen ausgewählt. Durch selektive Bindungseingenschaften der Nitroverbindungen an die α-CD Einheiten konnten verschiedene katalytische Aktivitäten für Nip and DMNip festgestellt werden. / The combination of inorganic nanoparticles and organic microgels in one hybrid system allows for the preparation of new materials with multifunctional properties. Ideally, such hybrid materials reflect both the properties of its individual components and synergetic effects due to the interaction between inorganic nanoparticles and microgels. In the first part of this thesis, the fabrication of Cu2O@Poly(N-isopropylacrylamide) (PNIPAM) core-shell nanoreactors has been presented. It was found that the PNIPAM shell effectively protects the Cu2O nanocubes from oxidation. The core-shell microgels have been used as photocatalyst for the decomposition of methyl orange and a significant enhancement in the catalytic activity has been observed compared with the bare Cu2O nanocubes. Most importantly, the photocatalytic activity of the core-shell nanoreactors can be further tuned by the thermosensitive PNIPAM shell. The aqueous solution of Cu2O@PNIPAM core-shell nanoparticles with quite low solid content (1.5wt. %) can be also directly used as a novel ink material for the inkjet printing without adding any other surfactants and organic solvents. The gas sensor device printed by core-shell nanoparticles is more sensitive to NO2 than that made from the bare Cu2O nanocubes. In the second part, a kind of hybrid microgel has been fabricated by immobilization of catalytically active Au nanoparticles in the α-cyclodextrin (α-CD) modified poly(N-vinylcaprolactam) (PVCL) microgels without addition of reducing agent and surfactant. The hybrid microgels can work efficiently as catalyst for the reduction of aromatic nitro-compounds by using the reduction of 4-nitrophenol (Nip) and 2,6-dimethyl-4-nitrophenol (DMNip) as model reactions. Due to the selective binding property of α-CDs to nitro compounds, the synthesized hybrid microgels show different catalytic activity for the target compounds, 4-nitrophenol (Nip) and 2,6-dimethyl-4-nitrophenol (DMNip), during the catalytic reactions. Katalyse Hybride Mikrogele Nnaoreaktoren Cu2O Nanowürfel Au Nanopartikel thermosensitiv Tintenstrahldruck Gas Sensor Cyclodextrin catalysis hybrid microgels nanoreactors Cu2O nanocubes Au nanoparticles thermosensitive inkjet printing gas sensor cyclodextrin 540 Chemie 30 Chemie VE 8007 VE 9857 VN 5807 ddc:540

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