Global ETD Search

71	Controlling Charge and Energy Transfer Processes in Artificial Photosynthesis : From Picosecond to Millisecond Dynamics Borgström, Magnus January 2005 (has links) This thesis describes an interdisciplinary project, where the aim is to mimic the initial reactions in photosynthesis. In photosynthesis, the absorption of light is followed by the formation of charge-separated states. The energy stored in these charge-separated states is further used for the oxidation of water and reduction of carbon dioxide. In this thesis the photo-induced processes in a range of supramolecular complexes have been investigated with time resolved spectroscopic techniques. The complexes studied consist of three types of units; photosensitizers (P) capable of absorbing light, electron acceptors (A) that are easily reduced and electron donors (D) that are easily oxidised. Our results are important for the future design of artificial photosystems, where the goal is to produce hydrogen from light and water. Two molecular triads with a D-P-A architecture are presented. In the first one, a photo-induced charge-separated state was formed in an unusually high yield (φ>90%). In the second triad, photo-irradiation led to the formation of an extremely long-lived charge-separated state (τ = 500 ms at 140K). This is also the first synthetically made triad containing a dinuclear manganese unit as electron donor. Further, two sets of P-A dyads are presented. In both, the expected photo-induced reduction of the electron acceptor is diminished due to competing energy transfer to the triplet state of the acceptor. Finally, a P-P-A complex containing two separate photosensitizers is described. The idea is to produce high-energy charge-separated states by using the energy from two photons. Physical chemistry Artificial photosynthesis Electron transfer Energy transfer Ruthenium Manganese Charge-separated state Donor-acceptor Fysikalisk kemi Physical chemistry Fysikalisk kemi
72	Molecular Approaches to Photochemical Solar Energy Conversion : Towards Synthetic Catalysts for Water Oxidation and Proton Reduction Eilers, Gerriet January 2007 (has links) A molecular system capable of photoinduced water splitting is an attractive approach to solar energy conversion. This thesis deals with the functional characterization of molecular building blocks for the three principal functions of such a molecular system: Photoinduced accumulative charge separation, catalytic water oxidation, and catalytic proton reduction. Systems combining a ruthenium-trisbipyridine photosensitizer with multi-electron donors in form of dinuclear ruthenium or manganese complexes were investigated in view of the rate constants of electron transfer and excited state quenching. The kinetics were studied in the different oxidation states of the donor unit by combination of electrochemistry and time resolved spectroscopy. The rapid excited state quenching by the multi-electron donors points to the importance of redox intermediates for efficient accumulative photooxidation of the terminal donor. The redox behavior of manganese complexes as mimics of the water oxidizing catalyst in the natural photosynthetic reaction center was studied by electrochemical and spectroscopic methods. For a dinuclear manganese complex ligand exchange reactions were studied in view of their importance for the accumulative oxidation of the complex and its reactivity towards water. With the binding of substrate water, multiple oxidation in a narrow potential range and concomitant deprotonation of the bound water it was demonstrated that the manganese complex is capable of mimicking multiple aspects of photosynthetic water oxidation. A dinuclear iron complex was investigated as biomimetic proton reduction catalyst. The complex structurally mimics the active site of the iron-only hydrogenase enzyme and was designed to hold a proton on the bridging ligand and a hydride on the iron centers. Thermodynamics and kinetics of the protonation reactions and the electrochemical behavior of the different protonation states were studied in view of their potential catalytic performance. Physical chemistry artificial photosynthesis solar fuel WOC OEC accumulative electron transfer hydrogenase mimic oxygen evolution proton reduction water oxidation Fysikalisk kemi
73	Proton-Coupled Electron Transfer from Hydrogen-Bonded Phenols Irebo, Tania January 2010 (has links) Proton-coupled electron transfer (PCET) is one of the elementary reactions occurring in many chemical and biological systems, such as photosystem II where the oxidation of tyrosine (TyrZ) is coupled to deprotonation of the phenolic proton. This reaction is here modelled by the oxidation of a phenol covalently linked to a Ru(bpy)32+-moitey, which is photo-oxidized by a laser flash-quench method. This model system is unusual as mechanism of PCET is studied in a unimolecular system in water solution. Here we address the question how the nature of the proton accepting base and its hydrogen bond to phenol influence the PCET reaction. In the first part we investigate the effect of an internal hydrogen bond PCET from. Two similar phenols are compared. For both these the proton accepting base is a carboxylate group linked to the phenol on the ortho-position directly or via a methylene group. On the basis of kinetic and thermodynamic arguments it is suggested that the PCET from these occurs via a concerted electron proton transfer (CEP). Moreover, numerical modelling of the kinetic data provides an in-depth analysis of this CEP reaction, including promoting vibrations along the O–H–O coordinate that are required to explain the data. The second part describes the study on oxidation of phenol where either water or an external base the proton acceptor. The pH-dependence of the kinetics reveals four mechanistic regions for PCET within the same molecule when water is the base. It is shown that the competition between the mechanisms can be tuned by the strength of the oxidant. Moreover, these studies reveal the conditions that may favour a buffer-assisted PCET over that with deprotonation to water solution. Proton-coupled electron transfer phenol oxidation hydrogen bonds artificial photosynthesis promoting vibrations proton transfer laser flash-quench transient absorption. Physical chemistry Fysikalisk kemi
74	Stepping into Catalysis : Kinetic and Mechanistic Investigations of Photo- and Electrocatalytic Hydrogen Production with Natural and Synthetic Molecular Catalysts Streich, Daniel January 2013 (has links) In light of its rapidly growing energy demand, human society has an urgent need to become much more strongly reliant on renewable and sustainable energy carriers. Molecular hydrogen made from water with solar energy could provide an ideal case. The development of inexpensive, robust and rare element free catalysts is crucial for this technology to succeed. Enzymes in nature can give us ideas about what such catalysts could look like, but for the directed adjustment of any natural or synthetic catalyst to the requirements of large scale catalysis, its capabilities and limitations need to be understood on the level of individual reaction steps. This thesis deals with kinetic and mechanistic investigations of photo- and electrocatalytic hydrogen production with natural and synthetic molecular catalysts. Photochemical hydrogen production can be achieved with both E. coli Hyd-2 [NiFe] hydrogenase and a synthetic dinuclear [FeFe] hydrogenase active site model by ruthenium polypyridyl photosensitization. The overall quantum yields are on the order of several percent. Transient UV-Vis absorption experiments reveal that these yields are strongly controlled by the competition of charge recombination reactions with catalysis. With the hydrogenase major electron losses occur at the stage of enzyme reduction by the reduced photosensitizer. In contrast, catalyst reduction is very efficient in case of the synthetic dinuclear active site model. Here, losses presumably occur at the stage of reduced catalyst intermediates. Moreover, the synthetic catalyst is prone to structural changes induced by competing ligands such as secondary amines or DMF, which lead to catalytically active, potentially mononuclear, species. Investigations of electrocatalytic hydrogen production with a mononuclear catalyst by cyclic voltammetry provide detailed kinetic and mechanistic information on the catalyst itself. By extension of existing theory, it is possible to distinguish between alternative catalytic pathways and to extract rate constants for individual steps of catalysis. The equilibrium constant for catalyst protonation can be determined, and limits can be set on both the protonation and deprotonation rate constant. Hydrogen bond formation likely involves two catalyst molecules, and even the second order rate constant characterizing hydrogen bond formation and/or release can be determined. Artificial photosynthesis photocatalysis electrocatalysis hydrogen production proton reduction hydrogenase iron complex active site model catalytic mechanism transient absorption spectroscopy electrochemistry cyclic voltammetry
75	Synthesis and investigation of an oxygen-evolving catalyst containing cobalt phosphate Larses, Patrik, Tegesjö, Lina January 2009 (has links) The experimental section in this thesis was based on the work of Kanan, M.W, et al reported in Science in December of 2008. A catalyst containing cobalt and phosphate was synthesized and used to decompose water into oxygen and hydrogen. This was done at nearly neutral pH. Cyclic voltammetry was performed to analyze the catalyst’s efficiency. Some surfaces were analyzed in a scanning electron microscope and the elemental composition was determined using energy-dispersive X-ray spectroscopy. A catalytic effect was observed at a potential of about 1,3 V. EDX showed Co at some of the surfaces. Quantum calculations were used to develop a model for the catalyst material. Molecular orbitals, interaction energies and vibrational frequencies were calculated for two different complexes of Co and phosphate. Patrik Larses was responsible for the electrochemical evaluation and synthesis in the experimental section of this thesis and Lina Tegesjö for the computational part. OEC cobalt phosphate artificial photosynthesis quantum calculations vibrational frequencies molecular orbitals cyclic voltammetry catalyst electrolysis hydrogen production renewable energy NATURAL SCIENCES NATURVETENSKAP
76	Redox-active ligand-mediated radical coupling reactions at high-valent oxorhenium complexes: reactions relevant to water oxidation for artificial photosynthesis Lippert, Cameron A. 07 July 2011 (has links) The making and breaking of O-O bonds has implications ranging from artificial photosynthesis and water oxidation to the use of O₂ as a selective, green oxidant for transformations of small molecules. Oxidative generation of O₂ from coupling of two H₂O molecules remains challenging, and well defined systems that catalytically evolve O₂ are exceedingly rare. Recent theoretical studies have invoked metal oxyl radicals (L[subscript n]M=O*) containing a singly occupied M-O π-type orbital as precursors to O-O bond forming events in both biological and synthetic water oxidation catalysts. However, the lack of stable metal oxyl complexes makes it difficult to explore and understand this hypothesis. The activation of dioxygen (breaking of O-O bonds) to produce terminal metal oxos also remains a challenge. There is an inherent kinetic barrier to the spin-forbidden reactions of triplet dioxygen, and features that engender selective O₂ reduction are not easily transferable from system to system. The primary thrust of this thesis work has been to elaborate new methods to generate well-defined metal oxyl radicals for studies of their reactions in radical bond-forming reactions similar to the radical coupling hypothesis of water oxidation. A library of >20 5- and 6-coordinate high-valent oxorhenium complexes containing redox-inert and redox-active ligands has been prepared. The complexes containing redox-active ligands have shown the ability for ligand-mediated radical coupling reactions. Mechanistic studies of bimetallic O₂ homolysis (the microscopic reverse of water oxidation) and nitroxyl radical deoxygenation at five-coordinate oxorhenium(V) reveal that, in both net 2e⁻ reactions, coupling to a redox-active ligand lowers the kinetic barrier to the reaction by facilitating formation and stabilization of 1e⁻ oxidized intermediates. Coordinatively unsaturated high-valent oxorhenium complexes containing redox-active ligands direct bond-forming reactions towards the metal center. This is undesirable towards the goal of forming O-O bonds. To address this problem coordinatively saturated Re(V) and Re(VII) complexes were prepared. Oxidation of these species by chemical oxidants allowed for the isolation of "masked" oxyl species. These complexes showed reactivity towards Si and trityl radicals to produce new Si-O and C-O bonds, whereas their closed-shell congeners were inert. We have successfully developed a method for the preparation and isolation of "masked" oxyl radicals and shown their utility in ligand-mediated radical coupling reactions. Inorganic synthesis Water oxidation Artificial photosynthesis Catalysis Photosynthesis Oxidation-reduction reaction Chemical reactions Inorganic compounds Synthesis Photosynthesis Industrial applications Oxidation-reduction reaction
77	Single and Accumulative Electron Transfer – Prerequisites for Artificial Photosynthesis Karlsson, Susanne January 2010 (has links) Photoinduced electron transfer is involved in a number of photochemical and photobiological processes. One example of this is photosynthesis, where the absorption of sunlight leads to the formation of charge-separated states by electron transfer. The redox equivalents built up by successive photoabsorption and electron transfer is further used for the oxidation of water and reduction of carbon dioxide to sugars. The work presented in this thesis is part of an interdisciplinary effort aiming at a functional mimic of photosynthesis. The goal of this project is to utilize sunlight to produce renewable fuels from sun and water. Specifically, this thesis concerns photoinduced electron transfer in donor(D)-photosensitizer(P)-acceptor(A) systems, in mimic of the primary events of photosynthesis. The absorption of a photon typically leads to transfer of a single electron, i.e., charge separation to produce a single electron-hole pair. This fundamental process was studied in several molecular systems. The purpose of these studies was optimization of single electron transfer as to obtain charge separation in high yields, with minimum losses to competing photoreactions such as energy transfer.Also, the lifetime of the charge separated state and the confinement of the electron and hole in three-dimensional space are important in practical applications. This led us to explore molecular motifs for linear arrays based on Ru(II)bis-tridentate and Ru(II)tris-bidentate complexes. The target multi-electron catalytic reactions of water-splitting and fuel production require a build-up of redox equivalents upon successive photoexcitation and electron transfer events. The possibilities and challenges associated with such processes in molecular systems were investigated. One of the studied systems was shown to accumulate two electrons and two holes upon two successive excitations, without sacrificial redox agents and with minimum yield losses. From these studies, we have gained better understanding of the obstacles associated with step-wise photoaccumulation of charge and how to overcome them. Artificial photosynthesis Photoinduced charge separation Electron transfer Energy transfer Accumulative electon transfer Donor-acceptor Ruthenium Linear arrays Chemical physics Kemisk fysik
78	Tuning of the Excited State Properties of Ruthenium(II)-Polypyridyl Complexes Abrahamsson, Maria January 2006 (has links) Processes where a molecule absorbs visible light and then converts the solar energy into chemical energy are important in many biological systems, such as photosynthesis and also in many technical applications e.g. photovoltaics. This thesis describes a part of a multidisciplinary project, aiming at a functional mimic of the natural photosynthesis, with the overall goal of production of a renewable fuel from sun and water. More specific, the thesis is focused on design and photophysical characterization of new photosensitizers, i.e. light absorbers that should be capable of transferring electrons to an acceptor and be suitable building blocks for supramolecular rod-like donor-photosensitizer-acceptor arrays. The excited state lifetime, the excited state energy and the geometry are important properties for a photosensitizer. The work presented here describes a new strategy to obtain longer excited state lifetimes of the geometrically favorable Ru(II)-bistridentate type complexes, without a concomitant substantial decrease in excited state energy. The basic idea is that a more octahedral coordination around the Ru will lead to longer excited state lifetimes. In the first generation of new photosensitizers a 50-fold increase of the excited state lifetime was observed, going from 0.25 ns for the model complex to 15 ns for the best photosensitizer. The second generation goes another step forward, to an excited state lifetime of 810 ns. Furthermore, the third generation of new photosensitizers show excited state lifetimes in the 0.45 - 5.5 microsecond region at room temperature, a significant improvement. In addition, the third generation of photosensitizers are suitable for further symmetric attachment of electron donor and acceptor motifs, and it is shown that the favorable properties are maintained upon the attachment of anchoring groups. The reactivity of the excited state towards light-induced reactions is proved and the photostability is sufficient so the new design strategy has proven successful. Physical chemistry Artificial photosynthesis Ruthenium(II) Bistridentate complexes Excited state lifetime Temperature dependence Excited state decay Fysikalisk kemi
79	Hybrid systems of molecular ruthenium catalyst anchored on oxide films for water oxidation: Functionality of the interface Scholz, Julius 26 June 2017 (has links) No description available. 530 Physik (PPN621336750) water oxidation artificial photosynthesis rotating ring-disk electrode manganite perovskite X-ray photoemission spectroscopy immobilization structural control stability
80	Photosynthèse artificielle : élaboration de matériaux composites pour la valorisation de CO2 par photocatalyse / Artificial photosynthesis : elaboration of composite materials for photocatalytic valorisation of CO2 Lofficial, Dina 07 October 2015 (has links) Une opportunité attrayante consisterait à utiliser l'énergie solaire, abondante et (quasi)inépuisable, pour valoriser le CO2 en carburants. Ceci permettrait de répondre à une double préoccupation : le dérèglement climatique imputable à l’augmentation de la concentration de gaz à effet de serre dans l’atmosphère d’une part, et d’autre part la raréfaction annoncée des ressources en énergie. Les végétaux sont capables de réduire le dioxyde de carbone en composés hydrogénocarbonés et d’oxyder simultanément l’eau en dioxygène par photosynthèse. Cette étude se propose d’élaborer des matériaux capables d’absorber la lumière et d’imiter le processus naturel, notamment son schéma énergétique en Z. La création de systèmes inorganiques comportant des hétérojonctions SCp (cathode) - Métal - SCn (anode) a été envisagée pour répondre à la problématique. Deux stratégies de synthèse ont alors été mises au point afin d’élaborer différents photocatalyseurs composite SCp@M/SCn notamment Cu2O@Pt/TiO2. L’évaluation des performances photocatalytiques a permis de révéler les bénéfices apportés par la présence d’hétérojunctions en termes de séparation des charges photogénérées et de sélectivité quant à la production de composés hydrogénocarbonés par photocatalyse. Ces travaux apportent une pierre importante à l’édifice d’un procédé de « photosynthèse artificielle » / An enticing opportunity would consist in using abundant and inexhaustible solar energy to valorise CO2 into fuels. That might answer in an elegant way to environmental and energetic concerns: the global warming due to atmospheric CO2 concentration increase and the dreaded shortage of energy resources. Green plants are able to reduce carbon dioxide into hydrocarbonated compounds and to oxidise simultaneously water into dioxygen by using photosynthesis. This study will focus on the design of materials able to absorb light and to imitate this natural process and more particularly its typical energetic Z-scheme. The chosen strategy is the creation of inorganic systems with SC-p (cathode) - Metal - SC-n (anode) heterojunctions. Two synthesis strategies were elaborated to obtain composite photocatalysts SCp@M/SCn, and more particularly Cu2O@Pt/TiO2. The evaluation of photocatalytic performances reveals heterojunctions benefits in term of charge separation and selectivity for photocatalytic hydrocarbonated compounds production. This study seems to do its bit towards “artificial photosynthesis” process Photosynthèse artificielle Réduction photocatalytique de CO2 Schéma en Z Hétérojonctions Photocatalyseur composite Cu2O Artificial photosynthesis CO2 photocatalytic reduction Z-Scheme Heterojonctions Hybrid photocatalyst Cu2O 541.395

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