Global ETD Search

51	Photocatalyseurs actifs dans le visible pour l'oxydation de l'eau : vers les bioraffineries solaires / Visible light-driven catalysts for water oxidation : towards solar fuel biorefineries Tolod, Kristine 06 May 2019 (has links) La séparation photoélectrochimique de l'eau (PEC) est un moyen direct de produire un combustible solaire tel que l'hydrogène à partir de l'eau. Le goulot d'étranglement de ce processus se situe dans la photoanode, qui est responsable du côté oxydation de la réaction1,2. Dans ce travail, l'utilisation de BiVO4 en tant que photoanode a été largement étudiée afin d'améliorer sa photoactivité. L’optimisation de la synthèse de photoanodes BiVO4 par électrodéposition en couche mince sur du FTO a été réalisée. Les facteurs influant sur l'activité photoélectrochimique, tels que le temps d'électrodéposition, le rapport Bi-KI/benzoquinone-EtOH dans le bain de dépôt et la température de calcination, ont été étudiés à l'aide de la conception composite centrale d'expériences. Les états de surface sur la surface de BiVO4 donnent lieu à des niveaux de défaut pouvant induire une recombinaison électron-trou via le mécanisme de Shockley-Read-Hall5. Afin de minimiser les inefficacités dues à la recombinaison électron-trou et passiver les états de surface, des couches de recouvrement ultra-fines d'Al2O3 et de TiO2 ont été déposées sur les électrodes en film mince BiVO4 d'une manière analogue à l'ALD. Cela a également été réalisé afin de protéger la surface de BiVO4 de la photocorrosion et d’augmenter sa stabilité. Une densité de photocourant de 0,54 mA/cm2 à 1,23 V vs RHE a été obtenue pour les 2 cycles de BiVO4 modifié par Al2O3, comme le montre la Figure 2, soit une amélioration de 54% par rapport à la BiVO4 nue qui démontrait une densité de photocourant de 0,35 mA/cm2. à 1,23 V vs RHE. Une augmentation de 15% de la stabilité de l'électrode de BiVO4 modifiée par Al2O3 a également été observée au cours de 7,5 heures d'irradiation continue. De plus, grâce aux mesures de capacité de surface présentées à la Figure 3, il a été montré que la surcouche de Al2O3 passivait effectivement à passiver les états de surface des électrodes de BiVO4. La nature de la surface de BiVO4 a été étudiée en étudiant la réactivité de la poudre de BiVO4 avec un titrant chimique. L’existence de groupes hydroxyle de surface sur BiVO4 a été confirmée et quantifiée (max. 1,5 OH / nm2) par titrage chimique. La réaction de la poudre de BiVO4 avec une impulsion de AlMe3 et une impulsion de H2O a montré qu'il existait 1,2 molécules de CH4 dégagées par Bi-OH. Dans ce travail, nous avons pu mettre en évidence les facteurs importants dans la synthèse de BiVO4 et leur incidence sur la photoactivité résultante. Nous avons également réussi à passiver les états de surface de BiVO4 en utilisant Al2O3, ce qui n’est pas bien exploré dans la littérature. De plus, nous avons pu sonder et discuter de la nature de la surface de BiVO4. Ceci est une connaissance très fondamentale et le premier rapport à ce sujet, à notre connaissance. Une bonne compréhension de cette surface semi-conductrice importante et de ses interactions facilitera la conception d'un photoanode BiVO4 plus efficace / Photoelectrochemical (PEC) water splitting is a direct way of producing a solar fuel like hydrogen from water. The bottleneck of this process is in the photoanode, which is responsible for the water oxidation side of the reaction1,2. In this work, the use of BiVO4 as a photoanode was extensively studied in order to improve its photoactivity. The optimization of BiVO4 photoanode synthesis via thin film electrodeposition on FTO was performed. The factors affecting the photoelectrochemical activity such as the electrodeposition time, ratio of the Bi-KI to benzoquinone-EtOH in the deposition bath, and the calcination temperature, have been investigated by using the Central Composite Design of Experiments.Surface states on the BiVO4 surface give rise to defect levels, which can mediate electron-hole recombination via the Shockley-Read-Hall mechanism5. In order to protect the BiVO4 surface and minimize the inefficiencies due to electron-hole recombination and passivate the surface states, ultrathin overlayers of Al2O3 and TiO2 were deposited to the BiVO4 thin film electrodes in an ALD-like manner. A photocurrent density of 0.54 mA/cm2 at 1.23 V vs RHE was obtained for the 2 cycles Al2O3-modified BiVO4, which was a 54% improvement from the bare BiVO4 that demonstrated a photocurrent density of 0.35 mA/cm2 at 1.23 V vs RHE. A 15% increase in stability of the Al2O3- modified BiVO4 electrode was also observed over 7.5 hours of continuous irradiation. Moreover, through surface capacitance measurements, it was shown that the Al2O3 overlayer was indeed passivating the surface states of the BiVO4 electrodes. The nature of the BiVO4 surface was studied by investigating the reactivity of powder BiVO4 with a chemical titrant. The existence of surface hydroxyl groups on BiVO4 was confirmed and quantified (max 1.5 OH/nm2) via chemical titration. The reaction of the BiVO4 powder with one pulse of AlMe3 and 1 pulse of H2O showed that there were 1.2 molecules of CH4 evolved per Bi-OH. In this work, we were able to highlight which factors are important in the synthesis of BiVO4, and how they affect the resulting photoactivity. We have also achieved the passivation of the BiVO4 surface states using Al2O3, which is not well-explored in literature. Moreover, we were able to probe and discuss the nature of the BiVO4 surface. This is a very fundamental knowledge and the first report of such, to the best of our knowledge. A good understanding of this important semiconductor surface and its interactions will aid in the design of a more efficient BiVO4 photoanode Photocatalyseurs BiVO4 Passivation Photocatalysts Photoanodes Photoelectrochemical water splitting BiVO4 Passivation 540
52	Advanced Carbon Materials for Environmental and Energy Applications Dua, Rubal 05 1900 (has links) Carbon based materials, including porous carbons and carbon layer composites, are finding increased usage in latest environmental and energy related research. Among porous carbon materials, hierarchical porous carbons with multi-modal porosity are proving out to be an effective solution for applications where the traditional activated carbons fail. Thus, there has been a lot of recent interest in developing low-cost, facile, easy to scale-up, synthesis techniques for producing such multi-modal porous carbons. This dissertation offers two novel synthesis techniques: (i) ice templating integrated with hard templating, and (ii) salt templating coupled with hard templating, for producing such hierarchically porous carbons. The techniques offer tight control and tunability of porosity (macro- meso- and microscale) in terms of both size and extent. The synthesized multi-modal porous carbons are shown to be an effective solution for three important environment related applications – (i) Carbon dioxide capture using amine supported hierarchical porous carbons, (ii) Reduction in irreversible fouling of membranes used for wastewater reuse through a deposition of a layer of hierarchical porous carbons on the membrane surface, (iii) Electrode materials for electrosorptive applications. Finally, because of their tunability, the synthesized multi-modal porous carbons serve as excellent model systems for understanding the effect of different types of porosity on the performance of porous carbons for these applications. Also, recently, there has been a lot of interest in developing protective layer coatings for preventing photo-corrosion of semiconductor structures (in particular Cu2O) used for photoelectrochemical water splitting. Most of the developed protective strategies to date involve the use of metals or co-catalyst in the protective layer. Thus there is a big need for developing low-cost, facile and easy to scale protective coating strategies. Based on the expertise gained in synthesizing porous carbon materials, and owing to our group’s interest in developing suitable photoelectrode materials, this dissertation also proposes a novel carbon-Cu2O composite comprising of a carbon layer coated Cu2O nanowire array structure as a high performance and stable photoelectrode material for photoelectrochemical water splitting. Porous Carbon Activated Carbon Heirarchical Porous Carbon CO2 captule Membrane Fouling capacitive Deionization water splitting
53	Electrical characterization of microwire-polymer assemblies for solar water splitting applications Yahyaie, Iman 03 1900 (has links) The increasing demand for energy and the pressure to reduce reliance on fossil fuels encourages the development of devices to harness clean and renewable energy. Solar energy is a large enough source to fulfill these demands, however, in order to overcome its daily and seasonal variability, it has been proposed that sunlight be harvested and stored in the form of chemical fuels. One potential approach is the photosynthetic splitting of water to store solar energy in the simplest chemical bond, H–H, using a device that includes: semiconducting microwire arrays as light harvesting components, redox catalysts, and a membrane barrier for separating the products of water redox reactions.. However, the harvested solar energy can be lost across the system and it is critical to characterize the electrical properties of each component within the system to quantify how much of this energy will ultimately be coupled to the water splitting reactions. The aim of this research is to develop approaches for characterization of a proposed system of this kind, incorporating individual semiconductor microwires as photoelectrodes (with no redox catalysts) embedded into a candidate conducting polymer membrane to form a single functional unit. Semiconductor microwires were isolated and using a novel contact formation approach with tungsten probes in a standard probe station, and their current versus voltage properties were characterized. This approach is of particular interest when ii considering the limitations of conventional contact formation approaches (e.g. thermal evaporation of contact metals), arising from the small dimensions of the microwires and also the incompatibility of these techniques with many microwire/polymer structures due to the unwanted interactions between polymers, photoresists, etchants and the high temperature lithographic processes. The electrical properties of different microwires and also the junctions between microwires and two candidate polymers were studied. Specifically, the combination of methyl-terminated silicon microwires and PEDOT:PSS:Nafion demonstrated promising behavior, with a total DC resistance of approximately 720 kΩ (i.e. losses < 16 mV at maximum available photocurrent), making it a suitable candidate for the use in the proposed system. The outcome of these research may be applied to many applications including semiconducting microstructures and conducting polymers. Solar water-splitting Artificial photosynthesis silicon microwire conducting polymers organic semiconductor
54	Electrical characterization of microwire-polymer assemblies for solar water splitting applications Yahyaie, Iman 03 1900 (has links) The increasing demand for energy and the pressure to reduce reliance on fossil fuels encourages the development of devices to harness clean and renewable energy. Solar energy is a large enough source to fulfill these demands, however, in order to overcome its daily and seasonal variability, it has been proposed that sunlight be harvested and stored in the form of chemical fuels. One potential approach is the photosynthetic splitting of water to store solar energy in the simplest chemical bond, H–H, using a device that includes: semiconducting microwire arrays as light harvesting components, redox catalysts, and a membrane barrier for separating the products of water redox reactions.. However, the harvested solar energy can be lost across the system and it is critical to characterize the electrical properties of each component within the system to quantify how much of this energy will ultimately be coupled to the water splitting reactions. The aim of this research is to develop approaches for characterization of a proposed system of this kind, incorporating individual semiconductor microwires as photoelectrodes (with no redox catalysts) embedded into a candidate conducting polymer membrane to form a single functional unit. Semiconductor microwires were isolated and using a novel contact formation approach with tungsten probes in a standard probe station, and their current versus voltage properties were characterized. This approach is of particular interest when ii considering the limitations of conventional contact formation approaches (e.g. thermal evaporation of contact metals), arising from the small dimensions of the microwires and also the incompatibility of these techniques with many microwire/polymer structures due to the unwanted interactions between polymers, photoresists, etchants and the high temperature lithographic processes. The electrical properties of different microwires and also the junctions between microwires and two candidate polymers were studied. Specifically, the combination of methyl-terminated silicon microwires and PEDOT:PSS:Nafion demonstrated promising behavior, with a total DC resistance of approximately 720 kΩ (i.e. losses < 16 mV at maximum available photocurrent), making it a suitable candidate for the use in the proposed system. The outcome of these research may be applied to many applications including semiconducting microstructures and conducting polymers. Solar water-splitting Artificial photosynthesis silicon microwire conducting polymers organic semiconductor
55	Synthesis and Characterisation of Ultra Thin Film Oxides for Energy Applications Fondell, Mattis January 2014 (has links) This thesis describes studies of materials which can be exploited for hydrogen production from water and sunlight. The materials investigated are maghemite (γ-Fe2O3), magnetite (Fe3O4) and especially hematite (α-Fe2O3), which is an iron oxide with most promising properties in this field. Hematite has been deposited using Atomic Layer Deposition (ALD) - a thin-film technique facilitating layer-by-layer growth with excellent thickness control and step coverage. The iron oxides were deposited using bis-cyclopentadienyl iron (Fe(Cp)2) or iron pentacarbonyl (Fe(CO)5) in combination with an O2 precursor. Since it is crucial to have good control of the deposition process, the influence of substrate, process temperature, precursor and carrier gas have been investigated systematically. By careful control of these deposition parameters, three polymorphs of iron oxide could be deposited: hematite (α-Fe2O3), maghemite (γ-Fe2O3) and magnetite (Fe3O4). The deposited materials were characterized using X-ray Diffraction, Raman and UV-VIS Spectroscopy, and Scanning Electron Microscopy. Hard X-ray Photoelectron Spectroscopy (HAXPES) was also used, since it is a non-destructive, chemically specific, surface sensitive technique – the surface sensitivity resulting from the short mean escape depth of the photoelectrons. The depth probed can be controlled by varying the excitation energy; higher photoelectron energies increasing the inelastic mean-free-path in the material. HAXPES studies of atomic diffusion from F-doped SnO2 substrates showed increased doping levels of Sn, Si and F in the deposited films. Diffusion from the substrate was detected at annealing temperatures between 550 °C and 800 °C. Films annealed in air exhibited improved photocatalytic behavior; a photocurrent of 0.23 mA/cm2 was observed for those films, while the as-deposited hematite films showed no photo-activity whatsoever. The optical properties of low-dimensional hematite were studied in a series of ultra-thin films (thicknesses in the 2-70 nm range). The absorption maxima were shifted to higher energies for films thinner than 20 nm, revealing a different electronic structure in thin films. Atomic Layer Deposition Iron oxides Hematite Solar Water Splitting Hard X-Ray Photoelectron Spectroscopy
56	Metal Hexacyanoferrate/Prussian Blue Analogue as a New Class of Promoters of Surface Redox Reactions for Efficient Photocatalytic Water Splitting / メタルへキサシアノフェレート/プルシアンブルー類縁体による水分解光触媒の表面酸化還元反応促進 Matsuoka, Hikaru 23 March 2022 (has links) 京都大学 / 新制・課程博士 / 博士(工学) / 甲第23914号 / 工博第5001号 / 新制\|\|工\|\|1781(附属図書館) / 京都大学大学院工学研究科物質エネルギー化学専攻 / (主査)教授阿部竜, 教授安部武志, 教授作花哲夫 / 学位規則第4条第1項該当 / Doctor of Philosophy (Engineering) / Kyoto University / DFAM Photocatalyst Water splitting Visible light Promoter Mediator Cyanoferrate Prussian blue 500
57	Design and Evaluation of a Concentrating Solar Power System with Thermochemical Water Splitting Process for the Co-production of Hydrogen and Electricity January 2018 (has links) abstract: Thermodynamic development and balance of plant study is completed for a 30 MW solar thermochemical water splitting process that generates hydrogen gas and electric power. The generalized thermodynamic model includes 23 components and 45 states. Quasi-steady state simulations are completed for design point system sizing, annual performance analysis and sensitivity analysis. Detailed consideration is given to water splitting reaction kinetics with governing equations generalized for use with any redox-active metal oxide material. Specific results for Ceria illustrate particle reduction in two solar receivers for target oxygen partial pressure of 10 Pa and particle temperature of 1773 K at a design point DNI of 900 W/m2. Sizes of the recuperator, steam generator and hydrogen separator are calculated at the design point DNI to achieve 100,000 kg of hydrogen production per day from the plant. The total system efficiency of 39.52% is comprised of 50.7% hydrogen fraction and 19.62% electrical fraction. Total plant capital costs and operating costs are estimated to equate a hydrogen production cost of $4.40 per kg for a 25-year plant life. Sensitivity analysis explores the effect of environmental parameters and design parameters on system performance and cost. Improving recuperator effectiveness from 0.7 to 0.8 is a high-value design modification resulting in a 12.1% decrease in hydrogen cost for a modest 2.0% increase in plant $2.85M. At the same time, system efficiency is relatively inelastic to recuperator effectiveness because 81% of excess heat is recovered from the system for electricity production 39 MWh/day and revenue is $0.04 per kWh. Increasing water inlet pressure up to 20 bar reduces the size and cost of super heaters but further pressure rises increasing pump at a rate that outweighs super heater cost savings. / Dissertation/Thesis / Doctoral Dissertation Mechanical Engineering 2018 Mechanical engineering Energy Chemical engineering Ceria Concentrated solar Co-production Solar fuels Water-splitting
58	Experimental and Computational Studies on the Design of Dyes for Water-splitting Dye-sensitized Photoelectrochemical Tandem Cells January 2014 (has links) abstract: Solar energy is a promising alternative for addressing the world's current and future energy requirements in a sustainable way. Because solar irradiation is intermittent, it is necessary to store this energy in the form of a fuel so it can be used when required. The light-driven splitting of water into oxygen and hydrogen (a useful chemical fuel) is a fascinating theoretical and experimental challenge that is worth pursuing because the advance of the knowledge that it implies and the availability of water and sunlight. Inspired by natural photosynthesis and building on previous work from our laboratory, this dissertation focuses on the development of water-splitting dye-sensitized photoelectrochemical tandem cells (WSDSPETCs). The design, synthesis, and characterization of high-potential porphyrins and metal-free phthalocyanines with phosphonic anchoring groups are reported. Photocurrents measured for WSDSPETCs made with some of these dyes co-adsorbed with molecular or colloidal catalysts on TiO2 electrodes are reported as well. To guide in the design of new molecules we have used computational quantum chemistry extensively. Linear correlations between calculated frontier molecular orbital energies and redox potentials were built and tested at multiple levels of theory (from semi-empirical methods to density functional theory). Strong correlations (with r2 values > 0.99) with very good predictive abilities (rmsd < 50 mV) were found when using density functional theory (DFT) combined with a continuum solvent model. DFT was also used to aid in the elucidation of the mechanism of the thermal relaxation observed for the charge-separated state of a molecular triad that mimics the photo-induced proton coupled electron transfer of the tyrosine-histidine redox relay in the reaction center of Photosystem II. It was found that the inclusion of explicit solvent molecules, hydrogen bonded to specific sites within the molecular triad, was essential to explain the observed thermal relaxation. These results are relevant for both advancing the knowledge about natural photosynthesis and for the future design of new molecules for WSDSPETCs. / Dissertation/Thesis / Ph.D. Chemistry 2014 Chemistry Energy DFT calculations Photoelectrochemical tandem cells Porphyrins and phthalocyanines Water splitting
59	Síntese de nanotubos obtidos pelo processo de anodização sob a liga Ti-75Ta como fotocatalisador para fotogeração de H₂ SOARES, Thiago André Salgueiro 25 January 2017 (has links) Submitted by Pedro Barros (pedro.silvabarros@ufpe.br) on 2018-07-19T20:29:07Z No. of bitstreams: 2 license_rdf: 811 bytes, checksum: e39d27027a6cc9cb039ad269a5db8e34 (MD5) DISSERTAÇÃO Thiago André Salgueiro Soares.pdf: 4033349 bytes, checksum: 4a1bb454487e180fb4adfc6bb7d4d5a2 (MD5) / Approved for entry into archive by Alice Araujo (alice.caraujo@ufpe.br) on 2018-07-20T22:05:04Z (GMT) No. of bitstreams: 2 license_rdf: 811 bytes, checksum: e39d27027a6cc9cb039ad269a5db8e34 (MD5) DISSERTAÇÃO Thiago André Salgueiro Soares.pdf: 4033349 bytes, checksum: 4a1bb454487e180fb4adfc6bb7d4d5a2 (MD5) / Made available in DSpace on 2018-07-20T22:05:05Z (GMT). No. of bitstreams: 2 license_rdf: 811 bytes, checksum: e39d27027a6cc9cb039ad269a5db8e34 (MD5) DISSERTAÇÃO Thiago André Salgueiro Soares.pdf: 4033349 bytes, checksum: 4a1bb454487e180fb4adfc6bb7d4d5a2 (MD5) Previous issue date: 2017-01-25 / CNPQ / Neste trabalho estudou-se a síntese de nanotubos (NT) a partir da liga Ti-75Ta através do processo de anodização e a sua aplicação como fotocatalisador na foto geração de hidrogênio (H₂). Através do planejamento fatorial 2³ completo foi possível a fabricação das nanoestruturas sob diferentes condições de potencial, tempo e temperatura e avaliar os feitos sob o campo elétrico do sistema (densidade de corrente) e a morfologia dos nanotubos (diâmetro e comprimento) e assim obter nanotubos com elevada área superficial especifica (62 m²/g). Os NT TiO₂-Ta₂O₅ sintetizados sob as diferentes condições experimentais foram caracterizados por microscopia eletrônica de varredura (MEV) permitindo mensurar os diâmetros e os comprimentos dos óxidos. As nanoestruturas quando formadas são amorfas necessitando de tratamento térmico para se obter a fase cristalina. A técnica de difração de Raios X (DRX) permitiu estudar a cinética de transformação das fases dos NT TiO₂-Ta₂O₅ e determinar que a temperatura de 800°C é a ideal para a obtenção das fases cristalinas sem danificar as nanoestruturas. Visando a formação de uma nova fase as amostras foram tratadas a 1000°C dando origem a um novo produto identificado como óxido misto de TiTa₂O₇, obtendo uma síntese simples e rápida para a fabricação deste material. A estrutura eletrônica foi avaliada através da técnica de espectroscopia de reflectância difusa, os NT TiO₂-Ta₂O₅ apresentaram band gap de 3,29eV, ao passo que os NT TiTa₂O₇ apresentaram band gap 3,09eV, potencializando a sua aplicação como fotocatalisador na reação de water splitting (WS). Desta forma, tentar combinar o processo de fotogeração de hidrogênio (WS) com a degradação de poluentes orgânicos é uma nova tendência mundial. Neste contexto, o glicerol foi utilizado como agente redutor e demonstrou ser um excelente agente de sacrifício, pois além de auxiliar na separação dos pares elétrons/buracos, apresentou longo tempo de estabilidade sem geração de CO₂ e a sua fotodegradação resultou na formação de dihidroxiacetona, como co-produto de alto valor agregado. Os nanotubos de sintetizados a 800°C apresentaram eficiência de conversão da energia solar em H₂ (STH) de 0,062% enquanto que os óxidos mistos apresentam STH de 0,092% resultados significativos admitindo ue são estruturas simples que permitem melhorias como a adição de catalisadores e dopantes. Além da aplicação como fotocatalisador o TiTa₂O₇ pode ser aplicado como ânodo em baterias de íon de Lítio, produto de grande impacto tecnológico. / In this work the synthesis of nanotubes (NT) from Ti-75Ta alloy (NT TiO₂-Ta₂O₅) was studied through the anodizing process and its application as photocatalyst in the hydrogen (H₂) photogeneration. Through the 2³ factorial design it was possible to fabricate nanostructures under different conditions of potential, time and temperature and to evaluate the effects under electric field of the system (current density) and the morphology of the nanotubes (diameter and length) to obtain nanotubes with Specific surface area (62 m²/g). The NT TiO₂-Ta₂O₅ synthesized as different experimental conditions were characterized by scanning electron microscopy (SEM) allowing to measure the diameters and the lengths of the oxides. As nanostructures when formed are amorphous requiring heat treatment to obtain a crystalline phase. The X-ray diffraction (XRD) technique allowed a transformation kinetics of the NT TiO₂-Ta₂O₅ phases and a temperature of 800 °C is an ideal for obtaining crystalline phases without damaging as nanostructures. Targeting a new phase formation as samples were treated at 1000 ° C to give a new product identified as TiTa₂O₇ mixed oxide, obtaining a simple and rapid synthesis for a manufacture of this material. The electronic structure was evaluated using the diffuse reflection spectroscopy technique, the NT TiO₂-Ta₂O₅ presented a band gap of 3.29eV, whereas the TiTa₂O₇ presented band gap 3.08eV, potentializing its application as a photocatalyst in the reaction of water splitting (WS). In this way, combining the hydrogen photogeneration (WS) process with a degradation of organic pollutants is a new world trend. Glycerol was used as a reducing agent and demonstrated to be an excellent reduction agent, besides assisting in the separation of e-/h+ pairs, presented long time of stability without generation of CO₂ and its photodegradation resulted in the formation of dihydroxyacetone, as coproduct of high added value. The nanotubes synthesized at 800 °C showed the conversion of solar energy to H₂ (STH) of 0.062% since the oxides are mixed have STH of 0.092% significant results admitted that are simple structures that stand out as an addition of noble metal nanoparticles and dopants. In addition to the application as a photocatalyst TiTa₂O₇ can be applied as an anode in Lithium ion batteries. Engenharia Química Óxidos Mistos Nanotubos Anodização Liga Ti-Ta Water Splitting
60	Photocatalyse de décomposition de l'eau : conception et construction d'une cellule photoelectrocatalyique pour la photodissociation de l'eau / Water splitting photoelectrocatalysis : the conception and construction of a photoelectrocatalytic water splitting cell Hilliard, Samantha 23 February 2016 (has links) La photoelectrocatalyse de l'eau par rayonnement solaire est une solution communément proposée pour la production propre d'hydrogène. En termes de rendement solaire-à-hydrogène, un tandem dual photosystème est accepté comme la configuration plus efficace concernant les cellules photoelectrocatalytique pour la dissociation de l'eau. Ce travail s'intéresse au trioxyde de tungstène (WO3) et au bismuth vanadate (BiVO4) sous la forme de photoanodes type n en couches minces pour la complétion d'oxydation de l'eau dans la demi-réaction pour la dissociation complète de l'eau dans une cellule tandem dual photosystème photoelectrocatalytique. Ces couches minces sont fabriquées par des méthodes robustes, économiques, et extensibles de sol-gel dip coating, et caractérisées par différentes techniques pour vérifier leurs caractéristiques physiques et leur performance photoelectrochimique. WO3 et BiVO4 sont optimises par nanostructuration, modification des couches interfaciales, et addition des co-catalyseurs de surface pour améliorer les performances et la stabilité, respectivement dans des conditions acides et neutres. Ces matériaux sont couples avec une photocathode de type p en oxyde de cuivre (II) pour compléter la réaction de dissociation de l'eau. La cellule photoelectrocatalytique ainsi construite est inspirée par la littérature concernant les systèmes innovateurs de tandem dual photosystèmes. Ce travail aboutit à l'une des seules cellules de dissociation de l'eau par photoelectrocatalyse à base des oxydes de métaux, fabriquée via des techniques faciles et économiques. L'efficacité de la production solaire-à-hydrogène est de 0.01%, et applied-bias-to-photon efficacité de 0.06%. / Solar water splitting by photoelectrocatalysis is a proposed long term solution for the production of renewable hydrogen. A wired dual photosystem photoelectrocatalytic cell is thermodynamically considered to possess the highest attainable solar-to-hydrogen efficiency. To realize a photoelectrocatalytic water splitting cell for practical application, facile fabrication methods and abundant low cost materials are essential. This research investigates tungsten trioxide (WO3) and bismuth vanadate (BiVO4) as thin film n-photoanodes to complete the oxygen evolution half reaction for water splitting application in a tandem dual photosystem photoeletrocatalyic water splitting cell. These thin films are fabricated by low cost, robust, scalable, sol-gel dip coating methods and characterized by several techniques to verify the physical characteristics and photochemical performance. WO3 and BiVO4 are optimized by nanostructuration, interfacial surface modification, and addition of surface co-catalysts to increase performance and stability in acidic and neutral conditions, respectively. These materials are coupled with a copper (II) oxide p-photocathode to drive the hydrogen evolution reaction in a photoelectrocatalyic cell to complete the water splitting reaction. The photoelectrocatalytic cell constructed is inspired by previous literature reports encompassing an innovative tandem dual photosystem approach. As a result, this research reports one of the only entirely metal oxide based photoelectrocatalytic water splitting cells, fabricated by inexpensive, unexcessive techniques, resulting in a solar-to-hydrogen efficiency of 0.01% and an applied bias to photon efficiency of 0.06%. Photocatalyse Photoelectrocatalyse Photodissociation de l'eau Bismuth vanadate Oxyde de tungstène Hydrogène propre Photoelectrocatalysis Water splitting Enewable hydrogen 541.3

Search results