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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
151

Structural and Photoelectrochemical Characterization of Gallium Phosphide Semiconductors Modified with Molecular Cobalt Catalysts

January 2018 (has links)
abstract: The molecular modification of semiconductors has applications in energy conversion and storage, including artificial photosynthesis. In nature, the active sites of enzymes are typically earth-abundant metal centers and the protein provides a unique three-dimensional environment for effecting catalytic transformations. Inspired by this biological architecture, a synthetic methodology using surface-grafted polymers with discrete chemical recognition sites for assembling human-engineered catalysts in three-dimensional environments is presented. The use of polymeric coatings to interface cobalt-containing catalysts with semiconductors for solar fuel production is introduced in Chapter 1. The following three chapters demonstrate the versatility of this modular approach to interface cobalt-containing catalysts with semiconductors for solar fuel production. The catalyst-containing coatings are characterized through a suite of spectroscopic techniques, including ellipsometry, grazing angle attenuated total reflection Fourier transform infrared spectroscopy (GATR-FTIR) and x-ray photoelectron (XP) spectroscopy. It is demonstrated that the polymeric interface can be varied to control the surface chemistry and photoelectrochemical response of gallium phosphide (GaP) (100) electrodes by using thin-film coatings comprising surface-immobilized pyridyl or imidazole ligands to coordinate cobaloximes, known catalysts for hydrogen evolution. The polymer grafting chemistry and subsequent cobaloxime attachment is applicable to both the (111)A and (111)B crystal face of the gallium phosphide (GaP) semiconductor, providing insights into the surface connectivity of the hard/soft matter interface and demonstrating the applicability of the UV-induced immobilization of vinyl monomers to a range of GaP crystal indices. Finally, thin-film polypyridine surface coatings provide a molecular interface to assemble cobalt porphyrin catalysts for hydrogen evolution onto GaP. In all constructs, photoelectrochemical measurements confirm the hybrid photocathode uses solar energy to power reductive fuel-forming transformations in aqueous solutions without the use of organic acids, sacrificial chemical reductants, or electrochemical forward biasing. / Dissertation/Thesis / Doctoral Dissertation Biochemistry 2018
152

\"Dependência da seletividade da reação de eletro-oxidação de metanol e etanol sobre nanopartículas de Pt/C e PtRh/C\" / \"Dependence of the selectivity of the methanol and ethanol electrooxidation reaction on Pt/C and PtRh/C nanoparticles\"

Bergamaski, Kleber 22 December 2005 (has links)
A eletro-oxidação de metanol e etanol é um tema ativamente estudado em eletrocatálise. O motivo da grande atenção dada à investigação da atividade eletrocatalítica destes álcoois é devido à procura de novos sistemas conversores de energia mais eficientes e menos poluidores. As pesquisas em eletrocatálise têm sido direcionadas também ao estudo de sistemas nanoparticulados. Partículas metálicas de tamanho nanométrico oferecem aspectos interessantes no estudo de efeitos estruturais em eletrocatalisadores dispersos. O decréscimo do tamanho de partícula promove uma utilização mais eficiente do catalisador, uma vez que a razão do número de átomos superficiais pelo número de átomos total é favorecida. Neste trabalho, investigou-se a oxidação eletroquímica de metanol e etanol sobre catalisadores de Pt e catalisadores de PtRh através da técnica de espectrometria de massas eletroquímica diferencial (DEMS). Nos catalisadores PtRh/C foi estudado o efeito da composição atômica do catalisador na reação de oxidação destes álcoois e nos catalisadores comerciais Pt/C E-Tek o efeito de tamanho de partícula na reação de oxidação de metanol. Na eletro-oxidação dos álcoois metanol e etanol sobre os catalisadores PtRh/C observou-se que a corrente faradáica decresceu em função do aumento de ródio no catalisador bimetálico. Por outro lado, a eficiência na oxidação completa do álcool a CO2 aumentou com a adição de ródio ao catalisador de platina. Atribuiu-se aos resultados obtidos com o catalisador PtRh/C, que o efeito eletrônico deve ter um papel importante no mecanismo de oxidação dos álcoois sobre estes catalisadores bimetálicos. No caso dos catalisadores Pt/C E-Tek o efeito do tamanho de partícula na reação de oxidação de metanol foi evidente. As medidas de eletro-oxidação de metanol mostraram uma eficiência alta na oxidação completa do álcool a CO2 sobre os catalisadores de carga metálica 30 e 40 %. Inferiu-se neste caso, que deve ser considerado não somente a morfologia da partícula, mas também o acoplamento entre partículas de tamanhos diferentes via produtos solúveis a fim de se obter um entendimento melhor do mecanismo global da reação. Sugeriu-se que há uma faixa de tamanho de partícula ótimo para a eletro-oxidação eficiente de metanol a CO2, de 3 a 10 nm. A perda em eficiência pode ser devido tanto a partículas muito pequenas quanto muito grandes conduzindo principalmente a oxidação parcial de metanol a formaldeído. / The methanol and ethanol electrooxidation is a subject of intense studies in electrocatalysis. The aim of such attention concerning this alcohol electrooxidation activity is due to development of new energy converter systems more efficient and less pollutant. The electrocatalysis research has been also directed to nanoparticle systems. Metallic particles in nanometric size offer interesting aspects for structural effects studies in supported electrocatalysts. The particle size decrease could promote efficient catalyst use, once the ratio number of superficial atoms/total atoms raises. In this work, the electrochemical oxidation of methanol and ethanol on Pt/C and PtRh/C catalysts through differential electrochemical mass spectrometry (DEMS) was investigated. The atomic composition effect in the alcohol oxidation was studied on PtRh/C catalysts. The particle size effect on methanol oxidation reaction was studied on Pt/C E-Tek catalysts. It has been observed in this bimetallic catalysts that the higher rhodium content, the lower faradaic current. On the other hand, the efficiency for complete methanol electrooxidation to CO2 increased with rhodium addition in the platinum catalyst. To these results were assigned that electronic effect plays a key role in the mechanism of alcohol oxidation on bimetallic catalysts. For Pt/C E-Tek catalysts ones, the particle size effect in the methanol oxidation reaction was more evident. Methanol electrooxidation measurements have shown a high efficiency for complete alcohol oxidation to CO2 on the 30 and 40 % wt. Pt/C catalysts. It was inferred, in this case, that must be consider not only the particle morphology but also the coupling between different size particles via soluble products in order to improve a better understanding of global reaction mechanism. It was suggested that there is an optimum particle size range for efficient methanol electrooxidation to CO2, that is, 3 to 10 nm range. The loss of efficiency could be due to very small particles or very great particles resulting in methanol partial oxidation mainly to formaldehyde.
153

CARBON QUANTUM DOTS: BRIDGING THE GAP BETWEEN CHEMICAL STRUCTURE AND MATERIAL PROPERTIES

Pillar-Little, Timothy J., Jr. 01 January 2018 (has links)
Carbon quantum dots (CQDs) are the latest generation of carbon nanomaterials in applications where fullerenes, carbon nanotubes, and graphene are abundantly used. With several attractive properties such as tunable optical property, edge-functionalization, and defect-rich chemical structure, CQDs have the potential to revolutionize optoelectronics, electro- and photocatalysis, and biomedical applications. Chemical modifications through the addition of heteroatoms, chemical reduction, and surface passivation are found to alter the band gap, spectral position, and emission pathways of CQDs. Despite extensive studies, fundamental understanding of structure-property relationship remains unclear due to the inhomogeneity in chemical structure and a complex emission mechanism for CQDs. This dissertation outlines a series of works that investigate the structure-property relationship of CQDs and its impact in a variety of applications. First, this relationship was explored by modifying specific chemical functionalities of CQDs and relating them to differences observed in optical, catalytic, and pharmacological performance. While a number of scientific articles reported that top-down or bottom-up synthesized CQDs yielded similar properties, the results herein present dissimilar chemical structures as well as photoluminescent and metal sensing properties. Second, the role of nitrogen heteroatoms in top-down synthesized CQD was studied. The effect of nitrogen atoms on spectral position and fluorescence quantum yield was considerably studied in past reports; however, thorough investigation to differentiate various nitrogen related chemical states was rarely reported. By finely tuning both the quantity of nitrogen doping and the distribution of nitrogen-related chemical states, we found that primary amine and pyridine induce a red-shift in emission while pyrrolic and graphitic nitrogen produced a blue-shift in emission. The investigation of nitrogen chemical states was extended to bottom-up synthesized CQDs with similar results. Finally, top-down, bottom-up, nitrogen-doped and chemically reduced CQDs were separately tested for their ability to act as photodynamic anti-cancer agents. This series of experiments uncovered the distribution of reactive oxygen species produced during light exposure which elucidated the photodynamic mechanisms of cancer cytotoxicity. The results presented in this dissertation provide key insight into engineering finely-tailored CQDs as the ideal nanomaterial for a broad range of applications.
154

Síntese e caracterização de eletrocatalisadores Pt-CeO2/C para eletro-oxidação de etanol em meio básico / Synthesis and characterization of Pt-CeO2 /C electrocatalyst for ethanol electro-oxidation in the alkaline medium

Venturini, Seiti Inoue 24 July 2019 (has links)
A produção de energia limpa e renovável é uma preocupação crescente da sociedade. Dentre as alternativas para produção de energia estão as células a combustível. Dentre os vários tipos de células, existem as PEMFC (Proton Exchange Membran Fuel Cell) que possuem vantagem de operar em baixa temperatura e podem utilizar como combustível hidrogênio ou álcoois. Porém as células PEM que utilizam álcool como combustível, ainda apresentam um rendimento inferior aquelas que operam com hidrogênio, além disso essas células requerem platina ou outros metais nobres porque somente estes materiais são relativamente estáveis nestas condições de pH. Nos últimos anos as células combustíveis alcalinas tem ganhado destaque devido à maior estabilidade dos eletrocalisadores, aumentando a possibilidade de utilização de metais não nobres ou óxidos metálicos. Neste trabalho, catalisadores do tipo Pt/C-CeO2 foram sintetizados sobre carbono de alta área superficial, variando-se a quantidade de CeO2 entre 0 a 10%. Os eletro-catalisadores contendo menor quantidade de óxidos apresentaram maior atividade frente a oxidação do etanol em meio básico. / The production of clean and renewable energy is a growing concern of society. Among the alternatives for energy production are fuel cells. Among the various types of cells, there are PEMFCs (Proton Exchange Membranes) which have the advantage of operating at low temperature and can use hydrogen or alcohols as fuel. However, PEM cells that use alcohol as fuel still have lower yields than those operating on hydrogen. In addition, these cells require platinum or other noble metals because only these materials are relatively stable under these pH conditions. In recent years alkaline fuel cells have gained prominence due to the greater stability of the electrocatalyst, increasing the possibility of using non-noble metals or metal oxides. In this work, catalysts like Pt-CeO2/C type were synthesized on carbon of high surface area, varying the amount of CeO2 between 0 and 10% (m/m). The electrocatalysts containing less oxides showed higher activity against the oxidation of ethanol in a basic medium.
155

Investigação de catalisadores bifuncionais para as reações de redução e evolução de oxigênio em meio ácido / Investigation of bifunctional catalysts for the oxygen reduction and evolution reactions in acidic medium

Silva, Gabriel Christiano da 09 August 2019 (has links)
Células a combustível regenerativas unitizadas (URFCs) são dispositivos eletroquímicos capazes de atuar como um eletrolisador de água ou como uma célula a combustível. Contudo, para que o potencial de uma URFC seja plenamente alcançado é essencial o desenvolvimento de componentes ativos e estáveis nos dois modos de operação, em especial em relação ao catalisador a ser utilizado no eletrodo de oxigênio. Em meio ácido, catalisadores obtidos pela combinação de platina e óxido de irídio têm apresentado desempenho satisfatório para as reações de redução (RRO) e evolução de oxigênio (REO), mas a estabilidade desses materiais ainda é relativamente pouco explorada. Neste trabalho, catalisadores bifuncionais foram sintetizados pela deposição de nanopartículas de platina sobre óxido irídio amorfo (Pt/IrOx) e cristalino (Pt/IrO2), e caracterizados físico-quimicamente através de diferentes técnicas, como EDX, XRD, XPS, XAS e XPS. A caracterização eletroquímica e a avaliação da atividade catalítica foi realizada em célula eletroquímica de três eletrodos, no qual é mostrado que, enquanto catalisadores Pt/IrO2 possuem maior atividade para a RRO, materiais Pt/IrOx são mais ativos para a REO. A estabilidade dos catalisadores bifuncionais foi avaliada empregando-se diferentes protocolos de envelhecimento. Uma investigação detalhada dos processos de degradação foi feita através da técnica de microscopia eletrônica de transmissão de localização idêntica (IL-TEM), enquanto que a dissolução eletroquímica dos catalisadores foi monitorada online utilizando-se uma célula eletroquímica de fluxo hifenada a um espectrômetro de massas com plasma indutivamente acoplado (SFCICP-MS). / Unitized regenerative fuel cells (URFCs) are electrochemical devices that can operate as a water electrolyzer or as a fuel cell. However, for the potential of an URFC to be fully achieved, it is essential to develop components that are active and stable in both operation modes, especially in relation to the catalyst to be used in the oxygen electrode. In acidic media, catalysts obtained by the combination of platinum and iridium oxide have shown satisfactory performance for the oxygen reduction (ORR) and evolution (OER) reactions, but the stability of these materials is still relatively little explored. In this work, bifunctional catalysts were synthesized by the deposition of platinum nanoparticles on hydrous (Pt/IrOx) and crystalline (Pt/IrO2) iridium oxide, and physicochemically characterized by different techniques such as EDX, XRD, TEM, XPS and XAS. The electrochemical characterization and the evaluation of the catalytic activity were performed in a three-electrodes electrochemical cell, in which it is shown that, while Pt/IrO2 catalysts have higher activity for the ORR, Pt/IrOx materials are more active for the OER. The stability of the bifunctional catalysts was evaluated using different aging protocols. A detailed investigation of the degradation processes was done using the identical location transmission electron microscopy (IL-TEM) technique, while the electrochemical dissolution of the catalysts was monitored online using a scanning flow cell inductively coupled to a plasma mass spectrometer (SFC-ICP-MS) setup.
156

Development of Transition Metal Carbide and Nitride Electrocatalysts for Chemical Energy Storage and CO2 Conversion

Tackett, Brian M. January 2019 (has links)
The rapid influx of solar energy and the desire to utilize carbon dioxide (CO2) will require large-scale energy storage and CO2 conversion technologies. Electrocatalytic devices can substantially impact both challenges, but improvements to electrocatalyst cost, activity, and selectivity are needed. Transition metal carbides provide a unique framework to reduce the loading of expensive catalyst metals while tuning the electrocatalytic activity and selectivity. Transition metal nitrides have many similar properties as carbides, and their synthesis inherently avoids the unwanted carbonaceous overlayer associated with carbide synthesis. Here it is shown that carbides and nitrides enable lower platinum-group metal (PGM) loadings and improve the activity and selectivity of electrocatalysts for reactions of water electrolysis and electrochemical CO2 reduction. Atom-thick layers of Pt were deposited onto niobium carbide (NbC) thin films to assess hydrogen evolution reaction (HER) activity. The Pt/NbC thin film, with one monolayer of Pt on NbC, performed similarly to bulk Pt. This correlated well with density functional theory (DFT) calculations of the hydrogen binding energy on the Pt/NbC surface. Potential applications of transition metal nitrides as electrocatalyst support materials were explored by synthesizing thin film nitrides of niobium and tungsten. The stability of each nitride was evaluated across broad potential-pH regimes to create a pseudo-Pourbaix diagram for each one. The films were each modified with atom-thick layers of Pt and were evaluated for HER performance in acid and alkaline electrolyte. Thin layers of Pt on WN and NbN showed Pt-like HER performance in acid and are promising candidates for high-surface area catalysts. To address the issue of high iridium (Ir) loading for the oxygen evolution reaction (OER) at the water electrolyzer anode, core-shell Ir-metal nitride particles were synthesized that contained 50% of the Ir mass loading of benchmark IrO¬2 particles. Iridium-iron nitride (Ir/Fe4N) showed increased activity on a mass-Ir basis and on a per-site basis, compared to IrO2. The core-shell morphology and stability under reaction conditions were confirmed with electron microscopy and in-situ X-ray absorption spectroscopy. Electrochemical reduction of CO2 to a mixture of CO and H¬2 (synthesis gas) was achieved on the palladium hydride (PdH) electrocatalyst. The product mixture can then be used as feedstock for the Fischer–Tropsch process and methanol synthesis. The syngas production performance was optimized by evaluating shape controlled PdH particles, bimetallic PdH, and PdH supported on transition metal carbides. At each step, the phase transition from Pd to PdH was monitored under reaction conditions with synchrotron-based X-ray absorption spectroscopy and X-ray diffraction. We also performed an overall carbon balance for catalytic transformation of CO2 to methanol via four reaction schemes, including one relying on electrocatalytic syngas production. The analysis revealed that hybrid electrocatalytic/thermocatalytic processes are most promising for resulting in overall CO2 reduction, but current densities of recently reported electrocatalysts need to increase to make the process economically feasible.
157

Hydrothermal and ionothermal carbon structures : from carbon negative materials to energy applications

Fellinger, Tim-Patrick January 2011 (has links)
The needs for sustainable energy generation, but also a sustainable chemistry display the basic motivation of the current thesis. By different single investigated cases, which are all related to the element carbon, the work can be devided into two major topics. At first, the sustainable synthesis of “useful” carbon materials employing the process of hydrothermal carbonisation (HC) is described. In the second part, the synthesis of heteroatom - containing carbon materials for electrochemical and fuel cell applications employing ionic liquid precursors is presented. On base of a thorough review of the literature on hydrothermolysis and hydrothermal carbonisation of sugars in addition to the chemistry of hydroxymethylfurfural, mechanistic considerations of the formation of hydrothermal carbon are proposed. On the base of these reaction schemes, the mineral borax, is introduced as an additive for the hydrothermal carbonisation of glucose. It was found to be a highly active catalyst, resulting in decreased reaction times and increased carbon yields. The chemical impact of borax, in the following is exploited for the modification of the micro- and nanostructure of hydrothermal carbon. From the borax - mediated aggregation of those primary species, widely applicable, low density, pure hydrothermal carbon aerogels with high porosities and specific surface areas are produced. To conclude the first section of the thesis, a short series of experiments is carried out, for the purpose of demonstrating the applicability of the HC model to “real” biowaste i.e. watermelon waste as feedstock for the production of useful materials. In part two cyano - containing ionic liquids are employed as precursors for the synthesis of high - performance, heteroatom - containing carbon materials. By varying the ionic liquid precursor and the carbonisation conditions, it was possible to design highly active non - metal electrocatalyst for the reduction of oxygen. In the direct reduction of oxygen to water (like used in polymer electrolyte fuel cells), compared to commercial platinum catalysts, astonishing activities are observed. In another example the selective and very cost efficient electrochemical synthesis of hydrogen peroxide is presented. In a last example the synthesis of graphitic boron carbon nitrides from the ionic liquid 1 - Ethyl - 3 - methylimidazolium - tetracyanoborate is investigated in detail. Due to the employment of unreactive salts as a new tool to generate high surface area these materials were first time shown to be another class of non - precious metal oxygen reduction electrocatalyst. / Die Notwendigkeit einer nachhaltigen Energiewirtschaft, sowie der nachhaltigen Chemie stellen die Motivation der vorgelegten Arbeit. Auf Grundlage separater Untersuchungen, die jeweils in engem Bezug zum Element Kohlenstoff stehen, kann die Arbeit in zwei Themenfelder geordnet werden. Der erste Teil behandelt die nachhaltige Herstellung nützlicher Kohlenmaterialien mit Hilfe des Verfahrens der hydrothermalen Carbonisierung. Im zweiten Teil wird die Synthese von Bor und Stickstoff angereicherten Kohlen aus ionischen Flüssigkeiten für elektrochemische Anwendungen abgehandelt. Insbesondere geht es um die Anwendung in Wasserstoff-Brennstoffzellen. Als Ergebnis einer sorgfältigen Literatur¬zusammenfassung der Bereiche Hydrothermolyse, hydrothermale Carbonisierung und Chemie des Hydroxymethylfurfurals wird ein chemisch-mechanistisches Modell zur Entstehung der Hydrothemalkohle vorgestellt. Auf der Basis dieses Modells wird ein neues Additiv zur hydrothermalen Carbonisierung von Zuckern vorgestellt. Die Verwendung des einfachen Additivs, genauer Borax, erlaubt eine wesentlich verkürzte und zu niedrigeren Temperaturen hin verschobene Prozessführung mit höheren Ausbeuten. Anhand des mechanistischen Modells wird ein Einfluss auf die Reaktion von Zuckern mit der reaktiven Kohlenvorstufe (Hydroxymethylfurfural) identifiziert. Die chemische Wirkung des Minerals Borax in der hydrothermalen Carbonisierung wird im Folgenden zur Herstellung vielfältig anwendbarer, hochporöser Kohlen mit einstellbarer Partikelgröße genutzt. Zum Abschluss des ersten Teils ist in einer Serie einfacher Experimente die Anwendbarkeit des mechanischen Modells auf die Verwendung „echter“ Biomasse in Form von Wassermelonenabfall gezeigt. Im zweiten Teil werden verschiedene cyano-haltige ionische Flüssigkeiten zur ionothermalen Synthese von Hochleistungskohlen verwendet. Durch Variation der ionischen Flüssigkeiten und Verwendung unterschiedlicher Synthesebedingungen wird die Herstellung hochaktiver, metallfreier Katalysatoren für die elektrochemische Reduktion von Sauerstoff erreicht. In der direkten Reduktion von Sauerstoff zu Wasser (wie sie in Brennstoffzellen Anwendung findet) werden, verglichen zu konventionellen Platin-basierten elektrochemischen Katalysatoren, erstaunliche Aktivitäten erreicht. In einem anderen Beispiel wird die selektive Herstellung von Wasserstoffperoxid zu sehr geringen Kosten vorgestellt. Abschließend wird anhand der Verwendung der ionischen Flüssigkeit 1-Ethyl-3-methylimidazolium-tetracyanoborat eine detaillierte Betrachtung zur Herstellung von graphitischem Borcarbonitrid vorgestellt. Unter Verwendung unreaktiver Salze, als einfaches Werkzeug zur Einführung großer inneren Oberflächen wird erstmals die elektrokatalytische Aktivität eines solchen Materials in der elektrochemischen Sauerstoffreduktion gezeigt.
158

Near-surface study of structure-property relationships in electrochemically fabricated multi-component catalysts

Rettew, Robert E. 21 September 2011 (has links)
This work outlines a series of developments and discoveries related to surface chemistry of controlled near-surface architectures. Through a combination of various X-ray spectroscopy techniques and innovative electrochemical fabrication techniques, valuable knowledge has been added to the fields of electrochemical fabrication, electrocatalysis, and fundamental surface chemistry. Described here is a specific new development in the technique of surface limited redox replacement (SLRR). This work, along with an accompanying journal publication1, reports the first-ever use of nickel as an intermediary for SLRR. In addition, this work identifies specific deviations from the nominal reaction stoichiometry for SLRR-grown films. This led to the proposal of a new reaction mechanism for the initial stages of the SLRR process, which will assist future fabrication attempts in this field. This work also discovered fundamental changes in Pt overlayer systems as the thickness of the overlayer on a gold support is increased from less than a single atomic monolayer to multilayer thicknesses. It was found that Pt overlayers below a certain threshold thickness exhibited increased affinity for hydroxyl groups, along with an increased propensity for formation of oxide and chloride species. These films were also studied for methanol, carbon monoxide, and ethylene glycol electro-oxidation. Finally, this work reports controlled surface architectures of Pt and Cu deposits on application-oriented TiO₂ nanotube arrays and Au-carbon supports.
159

Model Pt- and Pd-based Electrocatalysts for Low Temperature Fuel Cells Applications

Blavo, Selasi Ofoe 01 January 2013 (has links)
In the search for alternative energy technologies, low temperature fuel cells continue to feature as technologies with the most promise for mass commercialization. Among the low temperature fuel cells, alkaline and proton exchange membrane fuel cells are the most popular. Alkaline fuel cells have typically been used for water generation as well as auxiliary power for space shuttles. Their bulkiness however makes them undesirable for other applications, especially in automobiles, where there is a great demand for alternative technologies to internal combustion engines. Proton exchange membrane fuel cells on the other hand possess numerous qualities including their compact size, high efficiency and versatility. Their mass implementation has however been delayed, because of cost among other reasons. Most of this cost is owed to the Pt/C catalyst that accounts for about half of the price of the PEM Fuel Cell. This catalyst is used to drive the sluggish oxygen reduction reaction that occurs at the cathode of the PEM Fuel Cell. To overcome this obstacle, which is to make PEM Fuel Cell technology more affordable, reducing the amount Pt has traditionally been the approach. Another approach has been to find new ideal catalyst-support combinations that increase the intrinsic activity of the supported material. One more strategy has been to find lower cost alternative materials to Pt through synthetic and kinetic manipulations to rival or exceed the current oxygen reduction reaction activity benchmark. To this end, Palladium has garnered significant interest as a monometallic entity. Its manipulation through synthetic chemistry to achieve different morphologies - which favor select lattice planes - in turn promotes the oxygen reduction reaction to different degrees. In bimetallic or, in more recent times multimetallic frameworks, geometric and ligand effects can be used to form ideal compositions and morphologies that are synergistic for improved oxygen reduction reaction kinetics. In this dissertation, we have explored three different approaches to make contributions to the catalysis and electrocatalysis body of literature. In the first instance, we look at the influence of ligand effects through the active incorporation of a PVP capping agent on the stability of ~3nm Pt NPs. Washed (no capping agent) and unwashed (with capping agent) batches of NPs were evaluated via cyclic voltammogram analyses to evaluate differences there might be between them. It was found that the current density measurements for unwashed particle batches were higher. This increase in current density was attributed to the monodentate and bidentate ligand bonding from the PVP, which increased as a function of cycle number and plateaued when the PVP was completely decomposed. The complete decomposition of PVP during the CV experiment was estimated to occur around 200 cycles. The remaining portion of the dissertation explores the electrocatalytic properties of Palladium based NPs. The first instance, a monometallic study of Palladium cubes and dendrites was aimed at building on a recent publication on the enhanced ORR activity that was achieved with a PdPt bimetallic dendrite morphology. In our work, we sought to isolate the dendritic morphology properties of the monometallic Pd composition in order to understand what advantages could be achieved via this morphology. Pd cubes were used as a comparison, since they could be generated through the combination of a similar set of reagents simply by switching the order of addition. It was found that while there was no significant variation in the ORR activity as a function of morphology / shape, there was an interesting interaction between hydrogen and the palladium NPs in the hydrogen oxidation region that varied as a function of shape. This led to further sorption and ethylene hydrogenation studies, which suggested that, the interaction between hydrogen and Pd depended on the environment. Within the electrochemical environment, the ECSA measured, suggested that hydrogen was being reversibly absorbed into the sub-surface octahedral sites of Pd. The higher ECSA for Pd cubes corroborated with higher sorption for Pd cubes as well. However ethylene hydrogenation showed that the fringes of the Pd dendrites provided additional sites for reaction, which in turn translated to higher conversion. Furthermore, through a Koutecky-Levich analysis, it was found out that the Pd dendrites while exhibiting slightly lower activity, favored the 4-electron oxygen reduction process more than the Pd cubes. In the last part of this dissertation we explored the electrocatalytic properties of Pd-based bimetallic NPs under different morphologies including nanocages and sub-10nm alloys. With the inclusion of Ag, it was found out, through Koutecky-Levich analysis that the 4-electron process was better observed under alkaline conditions using a 0.1M NaOH(aq) electrolyte solution instead of a 0.1M HClO4 (aq) for acidic media testing. It was found that, for PdAg nanocage morphologies, where the Pd galvanically replaced the Ag to form cages, the four-electron process was suited to thinner Pd shells. Indeed the average electron numbers measured for Ag nanocubes coated with a 6nm shell was in agreement, within reason of literature values for bulk Ag. However, since the binding energy that both metals have for OH is so close, the potential for contributions to the ORR kinetics in alkaline media by Pd is a potential consideration.
160

The use of scanning electrochemical microscopy for the detection and quantification of adsorbed intermediates at electrodes

Rodriguez Lopez, Joaquin, 1983- 07 December 2010 (has links)
Scanning electrochemical microscopy (SECM) was used for the study and characterization of catalytic and electrocatalytic processes occurring at electrodes. The Surface Interrogation mode (SI-SECM) was introduced for the detection and quantification of adsorbed intermediates and products of catalyzed chemical and electrochemical reactions at noble metals (Pt, Au). In SI-SECM two micro electrodes (i.e. an SECM tip and a substrate of the desired material) are aligned concentrically at a micrometric distance where SECM feedback effects operate. A contrast mechanism based on feedback effects allows for the detection of reactive adsorbed intermediates at the substrate: the SECM tip generates a reactive homogeneous species that “micro-titrates” the substrate adsorbates to yield an electrochemical signal that contains information about the amount of intermediate and about its kinetics of reaction with the redox mediator. The technique was used for the study of the reactivity of three model small adsorbates: 1) the reactivity of adsorbed oxygen on Au and Pt with a reducing mediator was explored and suggested the detection of “incipient oxides” at these surfaces; kinetic parameters of the reactivity of Pt oxides with mediators were obtained, fit to theory and used to explain observations about the electrocatalytic behavior of Pt under anodizing conditions; 2) the reactivity of oxidizing mediators with adsorbed hydrogen on Pt was studied and showed the cation of N,N,N,N-tetramethyl-p-phenylenediamine (TMPD) to be a successful interrogation agent, the detection of hydrogen generated by the decomposition of formic acid on Pt at open circuit was investigated; 3) electrogenerated bromine was used to catalytically interrogate carbon monoxide at Pt, this reaction was previously unreported. The mentioned applications of SECM were validated through the use of digital simulations of diffusion in the complex SECM geometry through flexible commercial finite element method software. / text

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