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Carbon Monoxide Oxidation Under Oxidizing And Reducing Conditions With Alkali-metal And Palladium Doped Tin DioxideMirkelamoglu, Burcu 01 September 2006 (has links) (PDF)
The investigation of CO oxidation with supported noble metal catalysts to develop a fundamental understanding of the nature of the active sites, adsorbate-surface interactions, surface reaction pathways and the role of promoters is of prime importance for development of highly active and selective catalyst formulations for low temperature oxidation of carbon monoxide. Low temperature CO oxidation catalysts find applications in monitoring and elimination of CO in chemical process exhaust gases, in on-board control and diagnostics devices, automobile exhaust gas treatment systems for the development of zero-emission vehicles and, in closed-cycle CO2 lasers for remote sensing. Moreover, the investigation of the interaction of CO with noble metals and noble metals catalyzed oxidation of CO have important outcomes for upstream fuel processing systems and for the development of more CO tolerant anode materials for hydrogen fuel cell.
Palladized tin dioxide is a well-known and highly active catalyst for CO oxidation which possesses the potential to satisfy the need for CO oxidation catalysts in the abovementioned areas however, research on this material is concentrated mostly around empirical studies which focus solely on CO sensing applications. This current research is undertaken to investigate both the mechanism of CO oxidation with Pd/SnO2 at the molecular scale and the possibility of promoting the CO activity of this catalyst by the application alkali-metal modifiers.
Alkali-metal modified PdO/SnO2 catalysts were characterized by XPS, XRD and SEM and, tested with regard to their oxidation/reduction and CO oxidation behavior by in-situ dynamic methods such as, temperature-programmed reaction/reduction/desorption and impulse techniques. Modification of PdO/SnO2 by alkali-metals, namely Li, Na and K, resulted in catalyst formulations with different surface characteristics and reduction/oxidation behaviors that lead to superior activity in low temperature CO oxidation and selectivity towards CO in the presence of hydrogen. Studies have shown that these catalysts are potential candidates for CO oxidation catalysts in a wide range of areas.
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Structure Sensitivity Of Selective Co Oxidation Over Precious Metal CatalystsAtalik, Bora 01 February 2005 (has links) (PDF)
In this study, the effect of Pt particle size on the reaction rate and selectivity of preferential oxidation of CO (PROX) reaction was investigated on Pt/Al2O3. 2% Pt/& / #947 / -Al2O3 catalysts were prepared by incipient wetness method / the particle size of the catalysts was modified by calcination temperature and duration. Therefore, the relative amounts of low and high coordination atoms on the metal particle surface can be changed. Over these catalysts, first, the CO oxidation reaction was studied in the absence of hydrogen. The catalyst having the highest dispersion, i.e., lowest metal particle sizes, had the highest activity as indicated by its lowest light-off temperature. On the other hand, the turnover frequencies (TOF) of the catalysts were increasing with decreasing dispersion. The activation energy of the catalysts were also compared and examined: as the particle size increased, the activation energy decreased. In the second part, preferential oxidation of CO reaction in the presence of hydrogen was studied. Both CO conversion and selectivity first increased with increasing reaction temperature, then exhibited a maximum, and finally decreased. Both CO conversion and selectivity did not show any trend for different dispersed catalysts for & / #955 / (2PO2/PCO) was 1. In order to reach a definite conclusion about the structure sensitivity of selective CO oxidation, the experiments with different & / #955 / &rsquo / s and space times over the same catalysts should be performed.
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\"Estudo da eletro-oxidação de monóxido de carbono sobre eletrocatalisadores suportados por espectroscopia de impedância eletroquímica\" / Study of carbon monoxide electro-oxidation on supported electrocatalysts by electrochemical impedance spectroscopyEduardo Gonçalves Ciapina 16 February 2006 (has links)
O presente trabalho estudou comparativamente, do ponto de vista fundamental, a reação de eletro-oxidação de monóxido de carbono (CO) em meio ácido, sobre Pt75Sn25/C, Pt65Ru35/C e Pt/C através da Espectroscopia de Impedância Eletroquímica. Os materiais foram preparados por redução com ácido fórmico e caracterizados fisicamente por EDX e DRX de alta intensidade e eletroquimicamente por voltametria. Previamente aos estudos de Impedância, foram realizados estudos potenciodinâmicos da reação de eletro-oxidação de CO adsorvido (?Stripping de CO?) e a oxidação de CO em uma solução saturada de CO. Para os materiais Pt65Ru35/C e Pt/C, estes estudos mostraram que há um deslocamento de potencial do inicio da oxidação para valores mais positivos quando CO está presente em solução se comparado a oxidação (stripping) de CO, devido a competição de sítios de adsorção entre moléculas de CO e H2O, responsáveis pela reação. Por outro lado, no material bimetálico Pt75Sn25/C a presença de CO em solução não influenciou de maneira significativa o potencial de inicio da oxidação, confirmando a ausência de adsorção competitiva neste material. A curva de polarização em estado estacionário revelou que, dentre os 3 materiais estudados, o material bimetálico Pt75Sn25/C apresentou a maior atividade eletrocatalítica, isto é, maiores densidades de correntes em menores sobrepotenciais. Este comportamento foi, em grande parte, esclarecido através dos experimentos de Espectroscopia de Impedância Eletroquímica. Com a Espectroscopia de Impedância Eletroquímica foi verificada a formação de espécies oxigenadas em Pt/C e em Pt65Ru35/C no intervalo de freqüências estudado, enquanto que em Pt75Sn25/C os diagramas de impedância revelaram um comportamento predominantemente capacitivo, indicando a ausência de reações de transferência de carga devido à oxidação da H2O para formar hidróxidos/óxidos na superfície do material. Também foi demonstrado que os processos relacionados a reação entre COads e espécies oxigenadas superficiais são mais rápidos em Pt75Sn25/C do que em Pt/C e Pt65Ru35/C, como ficou evidente no diagrama de Bode do ângulo de fase em função da freqüência. Mais especificamente, a menor resistência de transferência de carga para a reação em Pt75Sn25/C aparece em freqüências mais altas provavelmente devido à reação ocorrer com espécies oxigenadas já presentes na fase SnO2 presente no material. Por outro lado, os processos de adsorção são mais rápidos devido a menor energia de adsorção de CO sobre Pt, de acordo com os resultados encontrados por cálculos teóricos de DFT. / In this work, kinetic aspects of CO electro-oxidation on Pt/C, Pt75Sn25/C and Pt65Ru35/C prepared by chemical reduction with formic acid were studied by Electrochemical Impedance Spectroscopy (EIS). The bulk composition of the asprepared PtSn/C and PtRu/C bimetallic materials, analyzed by EDX, was 77:23 and 64:36, respectively. Using high intensity XDR measurements the bulk structure and phase determinations could be established. The analysis of the XRD profiles of Pt75Sn25/C revealed partial alloy formation and the presence of a SnO2 phase. For Pt65Ru35/C, no alloy formation was verified. Potentiodynamic oxidation of CO in a CO-saturated solution compared with CO stripping voltammetry pointed out the presence of competitive adsorption between CO and oxygen containing species on the surface of Pt/C and Pt65Ru35/C while for Pt75Sn25/C no competition for surface sites was verified. Impedance measurements were conducted in two different conditions: i) in the absence of CO in solution and ii) in a CO saturated solution. Provided by an equivalent circuit the charge transfer resistance (Rct), was obtained for the studied materials. The mean double layer capacitance (Cdl) was also estimated from circuit parameters and revealed its dependence on the carbon monoxide surface coverage (_CO). Furthermore, the relation between the _CO and the charge transfer resistance for the reaction is discussed. Using EIS it was demonstrated that the Rct for the carbon monoxide electro-oxidation reaction on Pt75Sn25/C is much lower than on Pt/C and Pt65Ru35/C, which was related to the presence of oxygen-containing species already present in the SnO2 phase as well as to the faster adsorption processes on this material compared to Pt/C and Pt65Ru35/C.
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Design of Embedded Metal Catalysts via Reverser Micro-Emulsion System: a Way to Suppress Catalyst Deactivation by Metal SinteringAl Mana, Noor 19 June 2016 (has links)
The development of highly selective and active, long-lasting, robust, low-cost and environmentally benign catalytic materials is the greatest challenge in the area of catalysis study. In this context, core-shell structures where the active sites are embedded inside the protecting shell have attracted a lot of researchers working in the field of catalysis owing to their enhanced physical and chemical properties suppress catalyst deactivation. Also, a new active site generated at the interface between the core and shell may increases the activity and efficiency of the catalyst in catalytic reactions especially for oxide shells that exhibit redox properties such as TiO2 and CeO2. Moreover, coating oxide layer over metal nanoparticles (NPs) can be designed to provide porosity (micropore/mesopore) that gives selectivity of the various reactants by the different gas diffusion rates. In this thesis, we will discuss the concept of catalyst stabilization against metal sintering by a core-shell system. In particular we will study the mechanistic of forming core-shell particles and the key parameters that can influence the properties and morphology of the Pt metal particle core and SiO2 shell (Pt@SiO2) using the reverse micro-emulsion method. The Pt@SiO2 core-shell catalysts were investigated for low-temperature CO oxidation reaction. The study was further extended to other catalytic applications by varying the composition of the core as well as the chemical nature of the shell material.
The Pt NPs were embedded within another oxide matrix such as ZrO2 and TiO2 for CO oxidation reaction. These materials were studied in details to identify the factors governing the coating of the oxide around the metal NPs. Next, a more challenging system, namely, bimetallic Ni9Pt NPs embedded in TiO2 and ZrO2 matrix were investigated for dry reforming of methane reaction at high temperatures. The challenges of designing Ni9Pt@oxide core-shell structure with TiO2 and ZrO2 and their tolerance of the structure to the conditions of dry reforming of methane will be discussed.
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Studium inverzního katalyzátoru CeOx / Rhodium / Study of CeOx / Rh inverse catalystKettner, Miroslav January 2013 (has links)
Title: Study of CeOX / Rh inverse catalyst Author: Bc. Miroslav Kettner Department: Department of Surface and Plasma Science Supervisor: doc. RNDr. Václav Nehasil, Dr., Department of Surface and Plasma Science Abstract: Inverse catalysts of cerium oxide deposited on polycrystalline and monocrystalline (111) rhodium substrates were studied by means of surface science experimental methods. Growth characteristics of cerium oxide were investigated in dependence on deposition conditions and different thickness determination methods were compared. Acording to oxidizing or reducing exposition conditions changes in degree of oxidation of CeOX were observed. Further spectra analysis showed additional Ce-Rh alloy formation. Adsorption positions CO on-top and CO hollow on Rh (111) surface were differentiated by spectra fitting procedures. Oxygen absorption and reverse desorption in CeOX was confirmed. Performed experiments indicate that this process occurs through oxide-metal interface. CO oxidation reaction mechanisms at room temperature were proposed. Cerium oxide presence is necessary for reaction occurrence. Significant influence of deposited CeOX on proposed CO oxidation reaction mechanisms was proved by this way. Keywords: Rhodium, cerium oxide, alloy, inverse catalyst, CO oxidation.
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Studium oxidace CO a metanolu za vysokého tlaku na katalyzátorech ve formě nanoprášků oxidů kovů vzácných zemin a tenkých vrstev na bázi platiny / High pressure CO and methanol oxidation study over nanopowders Rare Earth Oxides and platinum thin film catalystsRednyk, Andrii January 2016 (has links)
Title: High pressure CO and methanol oxidation study over nanopowder Rare Earth Oxides and platinum thin film catalysts Author: Mgr. Andrii Rednyk Department: Department of Surface and Plasma Science Supervisor: Prof. RNDr. Vladimír Matolín, DrSc. matolin@mbox.troja.mff.cuni.cz Abstract: This doctoral thesis focuses on reactivity study of nanopowder rare earth oxides (REOs) and platinum based thin film catalysts using microreactor with high pressure reaction cell. REOs nanoparticles were prepared by new approach based on sol-gel chemistry. Magnetron sputtering technique was used for preparation of thin film samples. In the first part of the thesis CO oxidation on REOs and on Pt, PtOx thin films were performed. Among prepared REOs catalyst better activity exhibited alumina stabilized ceria, due to higher surface area. Both Pt and PtOx deposited on silicon substrate exhibited similar activity. When carbon (G-foil or C interlayer) is used as support, activity of Pt thin film decreases while PtOx preserves high activity. In the second part of the thesis steam reforming of methanol (SRM) and partial oxidation of methanol (POM) were performed on Pt thin films. It was shown that PtOx thin film exhibited superior activity compared to other samples with the same thickness. It is due to the reduction of platinum...
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Studium interakce systémů oxid ceru-kov s plyny - oxidace oxidu uhelnatého a dekompozice metanolu / Study of cerium oxide-metal interaction with gases - carbon monoxide oxidation and methanol decompositionKolářová, Tatiana January 2016 (has links)
Title: Study of cerium oxide-metal intraction with gases - carbon monoxide oxidation and methanol decomposition Author: Tatiana Kolářová Department: Department of Surface and Plasma Science Supervisor: Doc. RNDr. Václav Nehasil, Dr., Department of Surface and Plasma Science Abstract: Dissertation thesis is focused on the study of two catalytic systems on the basis of cerium oxide-metal. The systems were characterized by various methods of surface analysis. The first part of the work concerns influence of the preparation parameters on the character of gold nanoparticles deposited onto the sputtered cerium oxide layers from a solution. Catalytic activity of prepared Au/CeOx/(C)/Si systems, containing particles with the mean sizes of 4- 10 nm, was tested toward CO oxidation at atmospheric pressure. The results show that with increasing amount of gold present on the samples, also the productivity of CO2 during the reactions grows. The work is further focused on the preparation of an inverse model CeOx/Pt(111) system. On this system, adsorption of methanol at low temeperatures and its decomposition during a heating was studied. It is apparent from presented results that the decomposition of methanol on the inverse CeOx/Pt(111) systems behaves in a different way than on a clean platinum sample or a thick...
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Metaloxid katalysatorer för oxidering av kolmonoxid och förbränning av sot / Metal oxide catalysts for CO oxidation and soot combustionGÓMEZ AGUILERA, Miguel January 2015 (has links)
The aim of this work was to manufacture and test non noble metal catalysts for CO oxidation and soot combustion. The feeding gases consist in the products of the combustion diesel in a Reformtech heater. These gases contain CO, CO2, H2O as well as small amounts of NOx and hydrocarbons. Two different catalysts were prepared for CO oxidation, based on cobalt oxide supported on ceria. 12Co/CeO2 with 12% weight of cobalt and 15CoOx/CeO2 with 15%. The first one was prepared by impregnation of cobalt nitrates in cerium oxide support; the second one was prepared by co-precipitation of cobalt and cerium nitrates. Another catalyst called 12Co4.5K/CeO2, with 12% cobalt and 4.5% potassium, was made for the simultaneous combustion of soot and oxidation of CO. The base also consisted in cobalt oxide supported on ceria, but with the addition of potassium which could stabilize the cobalt oxide particles. Both co-precipitation and impregnation methods gave the desired catalyst structure in the CO oxidation catalysts and both catalysts (12Co/CeO2 and 15CoOx/CeO2) showed activity. Nevertheless, the activity was lower than desired due to low surface area and mass transfer limitations. The catalysts also deactivated in less than three hours on stream, probably due to poisoning. The co-precipitation method for the 12Co4.5K/CeO2 catalyst gave the desired cobalt and cerium oxides, but no conclusion can be drawn regarding potassium since it was not shown in the XRD tests. The catalyst for both CO oxidation and soot combustion (12Co4.5K/CeO2) showed no activity for any of the reactions. Nevertheless, the tests performed to test the soot combustion ability were not conclusive and should be improved in future studies.
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In-situ Gas Phase Catalytic Properties Of Metal NanoparticlesOno, Luis 01 January 2009 (has links)
Recent advances in surface science technology have opened new opportunities for atomic scale studies in the field of nanoparticle (NP) catalysis. The 2007 Nobel Prize of Chemistry awarded to Prof. G. Ertl, a pioneer in introducing surface science techniques to the field of heterogeneous catalysis, shows the importance of the field and revealed some of the fundamental processes of how chemical reactions take place at extended surfaces. However, after several decades of intense research, fundamental understanding on the factors that dominate the activity, selectivity, and stability (life-time) of nanoscale catalysts are still not well understood. This dissertation aims to explore the basic processes taking place in NP catalyzed chemical reactions by systematically changing their size, shape, oxide support, and composition, one factor at a time. Low temperature oxidation of CO over gold NPs supported on different metal oxides and carbides (SiO2, TiO2, TiC, etc.) has been used as a model reaction. The fabrication of nanocatalysts with a narrow size and shape distribution is essential for the microscopic understanding of reaction kinetics on complex catalyst systems ("real-world" systems). Our NP synthesis tools are based on self-assembly techniques such as diblock-copolymer encapsulation and nanosphere lithography. The morphological, electronic and chemical properties of these nanocatalysts have been investigated by atomic force microscopy (AFM), scanning tunneling microscopy (STM), transmission electron microscopy (TEM), X-ray photoelectron spectroscopy (XPS), and temperature-programmed desorption (TPD). Chapter 1 describes briefly the basic principles of the instrumentation used within this experimental dissertation. Since most of the state-of-art surface science characterization tools provide ensemble-averaged information, catalyst samples with well defined morphology and structure must be available to be able to extract meaningful information on how size and shape affect the physical and chemical properties of these structures. In chapter 2, the inverse-micelle encapsulation and nanosphere lithography methods used in this dissertation for synthesizing uniformly arranged and narrow size- and shape-selected spherical and triangular NPs are described. Chapter 3 describes morphological changes on individual Au NPs supported on SiO2 as function of the annealing temperature and gaseous environment. In addition, NP mobility is monitored. Chapter 4 explores size-effects on the electronic and catalytic properties of size-selected Au NPs supported on a transition metal carbide, TiC. The effect of interparticle interactions on the reactivity and stability (catalyst lifetime) of Au NPs deposited on TiC is discussed in chapter 5. Size and support effects on the formation and thermal stability of Au2O3, PtO and PtO2 on Au and Pt NPs supported on SiO2, TiO2 and ZrO2 is investigated in chapter 6. Emphasis is given to gaining insight into the role of the NP/support interface and that played by oxygen vacancies on the stability of the above metal oxides. Chapter 7 reports on the formation, thermal stability, and vibrational properties of mono- and bimetallic AuxFe1-x (x = 1, 0.8, 0.5, 0.2, 0) NPs supported on TiO2(110). At the end of the thesis, a brief summary describes the main highlights of this 5-year research program.
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Electrochemical and Surface-enhanced Raman Studies of CO and Methanol Oxidation in the Presence of Sub-monolayer Co-adsorbed SulfurMattox, Mathew Allen 01 December 2006 (has links)
No description available.
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