Global ETD Search

51	Does arbuscular mycorrhiza symbiosis increase the capacity or the efficiency of the photosynthetic apparatus in the model legume Medicago truncatula? Rehman, Ateeq ur January 2010 (has links) The Arbuscular mycorrhiza (AM) is an endosymbiont of higher plant roots. Most land plants and cultivated crops are concerned to AM symbiosis. This endosymbiosis is based on the mutual exchange of nutrients between plant and fungus. Therefore, AM symbiosis leads to an increased demand for photosynthetic products. The aim of this study was to investigate the pathway used by plants during AM symbiosis to increase photosynthetic performance. Therefore, we have carried out a systematic characterization of photosynthesis in Medicago truncatula (M. truncatula), which is a model legume. We observed colonization by the fungus in roots and that AM symbiosis increases the fresh and dry plant biomass. This could be attributed to an increase in both photosynthetic efficiency and capacity in AM plants. Consistent with these observations, AM symbiosis enhanced phosphorus uptake from the soil into roots, stems and leaves, as based on analyses of phosphorus content. Based on equal chl loading, no differences were found regarding D1, Lhcb1 and Lhcb2 protein content in four plant groups. This indicates similar ratio between chl and PSII proteins. Furthermore, AM symbiosis increases the amount of chlorophyll, steady state oxygen evolution activities, maximum quantum yield (Fv/Fm), and photosynthetic electron transport rate (about 5 fold). Nevertheless, photoprotection was not affected by AM symbiosis. We observed an increase in weight of seed/fruit and weight of seed/plant in AM plants (about 2 fold). Based on these results, we propose that AM symbiosis increases both the efficiency and the capacity of photosynthetic apparatus in the M. truncatula. NATURAL SCIENCES NATURVETENSKAP
52	Etude des réactions mettant en jeu l'oxygène dans un système électrochimique lithium-air aqueux rechargeable électriquement / Study of oxygen reactions in an aqueous lithium-air battery Moureaux, Florian 16 November 2011 (has links) Les systèmes électrochimiques lithium-air sont des concepts naissants mais exhibent des performances théoriques intéressantes qui laissent espérer une rupture technologique dans le domaine des batteries pour véhicule électrique. La possibilité d'atteindre une densité d'énergie supérieure à 500 Wh kg-1 est effectivement en ligne de mire. A contrario de la technologie lithium-air anhydre, les systèmes lithium-air aqueux n'ont, jusqu'à présent, fait l'objet d'aucune étude approfondie. Ce travail concerne donc le développement d'un système lithium-air aqueux, à trois électrodes, et vise également à améliorer nos connaissances fondamentales dans le domaine. La présente étude se focalise sur le compartiment positif de la cellule, dans lequel les réactions de l'oxygène sont mises en jeu. Dans un premier temps, une électrode spécifiquement dédiée à la réaction de dégagement d'oxygène a été élaborée à partir d'un acier 316L. L'étude de son comportement a révélé une bonne propension à catalyser la réaction de dégagement d'oxygène ainsi qu'une bonne stabilité sur 3 000 heures de fonctionnement. Néanmoins, d'importants problèmes de catalyse ont pu être observés et attribués à la présence des ions lithium dans l'électrolyte de la batterie. Les ions Li+ bloquent les transitions électrochimiques des sites actifs à l'origine des propriétés d'électrocatalyse. Le comportement d'une électrode à air, composée de carbone et d'oxydes de manganèse, a par la suite été caractérisé dans ce milieu. L'étude révèle deux phénomènes importants réduisant la performance de l'électrode et dont l'origine a également été attribuée aux ions lithium : un blocage des transitions (MnIII/MnIV), et une stabilisation des groupements oxygénés à la surface du carbone. Pour finir, il a été proposé d'optimiser le système électrolytique en limitant l'activité des ions Li+ en solution et ainsi d'améliorer le rendement en potentiel de charge/décharge de la batterie. / The electrochemical lithium-air devices are emerging concepts and their very high theoretical performances have attracted a lot of attention, especially for an application in the electrical vehicle. A target of at least 500 Wh kg-1 is aimed for. The aqueous lithium-air devices have not yet been studied in detail which is not the case for the anhydrous lithium-air technology. This thesis firstly deals with the development of an aqueous lithium-air cell based on a three electrodes setup, and secondly attempts to improve our theoretical knowledge of these systems. This study particularly focuses on the positive compartment of the cell in which oxygen reactions occur. The first section is dedicated to the development of an oxygen evolution electrode made of 316L stainless steel. The study shows its ability to catalyze the oxygen evolution reaction as well its good stability over 3 000 hours of operation. Nevertheless, major problems of catalysis were observed and assigned to the presence of lithium ions in the electrolyte. Li+ ions inhibit the electrochemical oxidation of the active sites, which are needed for the electrocatalytic properties. The behavior of an air cathode was characterized in the same medium. The results show two important phenomena which reduces the electrode performance and which are also attributed to lithium ions : a deactivation of the (MnIII/MnIV) transition and a stabilization of the oxygenated groups at the carbon surface. Finally, an optimization of the electrolytic system was proposed by limiting the Li+ ions activity in solution, which improves the charge/discharge potential efficiency of the battery. Accumulateur lithium-air aqueux Réaction de dégagement de l'oxygène Réaction de réduction de l'oxygène Electrocatalyse LiOH saturé Lithium-air battery Oxygen evolution reaction Oxygen reduction reaction
53	Synthèse et caractérisation de matériaux électrocatalytiques : activation anodique de l'eau dans un électrolyseur PEM / Synthesis and characterization of electrocatalytic materials : anodic activation of oxygen evolution reaction in a PEM electrolyzer Audichon, Thomas 13 November 2014 (has links) Le dihydrogène se présente comme un vecteur énergétique d'avenir pour la diversification des sources de production d'énergie. L'électrolyse de l'eau dans le système PEMWE (Proton Exchange Membrane Water Electrolyzer) permet l'obtention de dihydrogène de grande pureté. Les atouts de cette technologie induite par l'utilisation d'assemblage membrane électrode (AME) permettent son couplage aux énergies renouvelables. Toutefois, l'amélioration de l'activité catalytique des matériaux anodiques et leur stabilité pour baisser la tension de cellule et la diminution de la teneur en métaux nobles dans la composition des matériaux sont nécessaires.Lors de ces travaux de thèse, une voie de synthèse a été élaborée pour préparer des nanomatériaux à base de ruthénium. L'ajout d'iridium a permis dans un premier temps de prévenir l'oxyde de ruthénium de la dissolution tout en maintenant l'activité du catalyseur initial. Les meilleures performances catalytiques des AMEs en termes de densité de courant, de tension de cellule et de durabilité ont été délivrées avec les matériaux anodiques dont la composition molaire en Ru est supérieure à 70 %. La substitution partielle des métaux précieux (Ru et Ir) par du cérium et du niobium dans le but de proposer des catalyseurs à moindre coût a été aussi réalisée. Contrairement au niobium qui apporte une phase amorphe dans la structure du matériau, le cérium jusqu'à une teneur de 10 % permet de conserver les performances de l'anode telles que obtenues dans le matériau bimétallique. Le cérium se présente donc comme un métal prometteur à intégrer de manière appropriée dans la composition des matériaux anodiques. / Hydrogen seems to be the most promising energetic vector in order to diversify the sources of energy production. Water splitting in a Proton Exchange Membrane Water Electrolyzer (PEMWE) provides a sustainable way of producing clean hydrogen. One of the main advantages of this technology based on the utilization of Membrane Electrode Assembling (MEA) is its potential coupling with renewable energy sources. However, the improvement of the catalytic activity of anode materials, their stability and the reduction of the noble metal content in their composition are required.During this thesis work, a new synthesis approach that consists in hydrolysis of metallic precursors in ethanol medium has been undertaken to prepare non-supported ruthenium-based nanomaterials. The addition of iridium to the nanocatalysts composition prevents the ruthenium oxide from dissolution without decreasing the initial activity of the anode catalyst. The best catalytic performance of MEAs in terms of current density, cell voltage and durability were observed with anode materials whose ruthenium molar composition is higher than 70 %. The partial substitution of precious metals (Ru and Ir) either by cerium or niobium with the purpose of decreasing the catalysts cost was also attempted. While the substitution with niobium introduces an amorphous phase in the material structure, the trimetallic materials containing cerium were shown to be crystalline. Furthermore, cerium contents up to 10 % allows maintaining the catalytic activity of the trimetallic anode close to that obtained with the bimetallic oxide material. Thus cerium appears as a promising metal to include in a suitable way on the composition of anode materials. Électrocatalyse Nanomatériaux à base de ruthénium Réaction de dégagement d'oxygène Impédance électrochimique Électrolyse de l'eau Electrocatalysis Ruthenium based nanomaterials Oxygen evolution reaction Electrochemical impedance Water electrolysis 541.395
54	Theoretical description of water splitting on TiO2 and combined Mo2C-graphene based materials Rodríguez Hernández, Fermín 22 August 2017 (has links) (PDF) The electrocatalytic water decomposition has been investigated in this thesis by means of its two half standard reactions: the oxygen evolution reaction (OER) and the hydrogen evolution reaction (HER). These reactions occur in different locations in a typical electrochemical cell: the anode and the cathode, respectively. Motivated by the lack of understanding about the reaction mechanisms occurring at the anodes and cathodes, we have proposed first: novel representations of typical TiO2 surfaces, based on small cluster systems, which can be used for a quick and more detailed assessment of the OER activities at modified TiO2 surfaces, and secondly we investigated the HER in two sets of model surfaces which represent recently synthesized materials, based on Mo2C and graphene with promising activities toward the HER. We have employed Density Functional Theory (DFT) based methods within both localized and extended basis sets, as implemented in GAMESS and VASP packages, respectively, to examine the structural, electronic and vibrational properties of the proposed models. We propose new reaction mechanisms for the OER on a number of molecular representations of TiO2 electrodes. For each reaction pathway, the free energy profile is computed, at different biases, from the DFT energies, the entropic and the zero-point energy contributions. The mechanisms explored in this thesis are found to be energetically more feasible than alternative reaction pathways considered in previous theoretical works based on molecular representations of the TiO2 surfaces. The representation of the surface of specific, commonly occurring, titanium dioxide crystals (e.g., rutile and anatase) within the small cluster approximation is able to reproduce qualitatively the rutile (110) outperforming of the anatase (001) surface. We subsequently investigate the influence of doping TiO2 surfaces with transition metals (TMs) on the performance of TiO2 -based electrodes for the water splitting electrochemical reaction. Two cluster models of the TM-doped active sites which resemble both the TiO2 anatase (001) and rutile (110) surfaces, respectively, are considered for the evaluation of the water decomposition reaction when a Ti is replaced by a TM atom. A set of TMs spanning from Vanadium to Nickel is considered. The late TMs explored here: Fe, Co and Ni are found to reproduce the observed experimental trends for the overpotentials in TiO2-doped electrodes. In the case of Cr and Mn, the present study predicts an enhancement of the OER activity for the anatase-like clusters while a reduction of this activity is found for the rutile-like ones. The vanadium-doped structures do not show relevant influence in the OER activity compared to pure TiO2-based cluster models. The last part of this work is devoted to the theoretical study of the HER on recently found materials based on the synergistic combination of molybdenum carbide and graphene layers. We propose two major structural models to describe the HER mechanism within the framework of DFT: Mo2C-based clusters adsorbed on carbon nanosheets and the Mo2C (001) surface covered by pure and nitrogen-doped graphene layers. The former system evaluates the influence of Mo2C nanoparticles adsorbed on carbon nanosheets towards the HER. The second one is employed to gain insight about the high HER activity observed in molybdenum carbide anchored on nitrogen-doped porous carbon nanosheets (Mo2C@2D-NPC), recently synthesized. The H-adsorption free energy has been used as a principal descriptor to asses the HER activity at the proposed model active sites. It resembles the value for the best state of the art catalyst for the HER (i.e., platinum at carbon substrate Pt@C) in some of the proposed structural models. Furthermore, a pH-correction is added within a simplified model, to the H-adsorption free energy barrier in every proposed structure. The pH dependence of the H-adsorption free energy barriers allows the assessment of the HER at acidic and alkaline conditions simultaneously. An overall agreement with experimental results is found and further predictions, promoting the development of better HER catalysts, have been done. Wasserspaltung Sauerstoff-Evolutionsreaktion Wasserstoff-Evolutionsreaktion Molekulare Modelle Oberflächenreaktionen Water splitting Oxygen evolution reaction Hydrogen evolution reaction Molecular models Surface reactions ddc:540 rvk:VE 7007
55	In-Situ Environmental TEM Studies of Electro- and Photo-Electrochemical Systems for Water Splitting Ronge, Emanuel 18 December 2020 (has links) No description available. 530 Physik (PPN621336750) water splitting oxygen evolution hydrogen evolution manganese oxide photo-cathode electrochemical corrosion TiO2 protection layer molybdenum sulfides catalysis ion-exchange in-situ microscopy surface dynamics
56	Theoretical description of water splitting on TiO2 and combined Mo2C-graphene based materials Rodríguez Hernández, Fermín 08 October 2017 (has links) The electrocatalytic water decomposition has been investigated in this thesis by means of its two half standard reactions: the oxygen evolution reaction (OER) and the hydrogen evolution reaction (HER). These reactions occur in different locations in a typical electrochemical cell: the anode and the cathode, respectively. Motivated by the lack of understanding about the reaction mechanisms occurring at the anodes and cathodes, we have proposed first: novel representations of typical TiO2 surfaces, based on small cluster systems, which can be used for a quick and more detailed assessment of the OER activities at modified TiO2 surfaces, and secondly we investigated the HER in two sets of model surfaces which represent recently synthesized materials, based on Mo2C and graphene with promising activities toward the HER. We have employed Density Functional Theory (DFT) based methods within both localized and extended basis sets, as implemented in GAMESS and VASP packages, respectively, to examine the structural, electronic and vibrational properties of the proposed models. We propose new reaction mechanisms for the OER on a number of molecular representations of TiO2 electrodes. For each reaction pathway, the free energy profile is computed, at different biases, from the DFT energies, the entropic and the zero-point energy contributions. The mechanisms explored in this thesis are found to be energetically more feasible than alternative reaction pathways considered in previous theoretical works based on molecular representations of the TiO2 surfaces. The representation of the surface of specific, commonly occurring, titanium dioxide crystals (e.g., rutile and anatase) within the small cluster approximation is able to reproduce qualitatively the rutile (110) outperforming of the anatase (001) surface. We subsequently investigate the influence of doping TiO2 surfaces with transition metals (TMs) on the performance of TiO2 -based electrodes for the water splitting electrochemical reaction. Two cluster models of the TM-doped active sites which resemble both the TiO2 anatase (001) and rutile (110) surfaces, respectively, are considered for the evaluation of the water decomposition reaction when a Ti is replaced by a TM atom. A set of TMs spanning from Vanadium to Nickel is considered. The late TMs explored here: Fe, Co and Ni are found to reproduce the observed experimental trends for the overpotentials in TiO2-doped electrodes. In the case of Cr and Mn, the present study predicts an enhancement of the OER activity for the anatase-like clusters while a reduction of this activity is found for the rutile-like ones. The vanadium-doped structures do not show relevant influence in the OER activity compared to pure TiO2-based cluster models. The last part of this work is devoted to the theoretical study of the HER on recently found materials based on the synergistic combination of molybdenum carbide and graphene layers. We propose two major structural models to describe the HER mechanism within the framework of DFT: Mo2C-based clusters adsorbed on carbon nanosheets and the Mo2C (001) surface covered by pure and nitrogen-doped graphene layers. The former system evaluates the influence of Mo2C nanoparticles adsorbed on carbon nanosheets towards the HER. The second one is employed to gain insight about the high HER activity observed in molybdenum carbide anchored on nitrogen-doped porous carbon nanosheets (Mo2C@2D-NPC), recently synthesized. The H-adsorption free energy has been used as a principal descriptor to asses the HER activity at the proposed model active sites. It resembles the value for the best state of the art catalyst for the HER (i.e., platinum at carbon substrate Pt@C) in some of the proposed structural models. Furthermore, a pH-correction is added within a simplified model, to the H-adsorption free energy barrier in every proposed structure. The pH dependence of the H-adsorption free energy barriers allows the assessment of the HER at acidic and alkaline conditions simultaneously. An overall agreement with experimental results is found and further predictions, promoting the development of better HER catalysts, have been done. info:eu-repo/classification/ddc/540 ddc:540
57	Zkoumání tenkovrstvého katalyzátoru na bázi Ir(Ox)-Ru(Oy) pro reakci vzniku kyslíku v elektrolyzéru vody s protonově vodivou membránou / Investigation of Ir(Ox)-Ru(Oy) thin-film catalysts for oxygen evolution reaction in proton exchange membrane water electrolyzers Hrbek, Tomáš January 2021 (has links) The main focus of this master thesis is the investigation of the anode catalysts for the Proton Exchange Membrane Water Electrolyzers (PEM-WEs). PEM-WEs play a pivotal role in the hydrogen economy concept as they allow water decomposition into oxygen and hydrogen. However, their operation requires expensive noble metal catalysts, i.e., iridium or platinum. This issue has yet to be solved to mass-produce PEM-WEs. Consequently, our main objective is to reduce the amount of iridium on the anode of PEM-WEs. We addressed this objective by two distinct approaches: morphological and chemical. With the morphological approach, plasma etching of the membrane and the magnetron sput- tering of CeO2 served to increase the membrane's active surface. Hence we improved the catalysts utilization. With the chemical approach, we focused on the catalyst itself. Thus, we replaced the pure iridium catalyst with a bimetallic iridium-ruthenium one. Therefore, the activity of the catalyst was enhanced while its price got reduced. To ex- plain and describe the catalyst's behavior, we used various electrochemical methods and surface analysis techniques. Finally, we combined both approaches to obtain one active, stable, and low-iridium-loading anode catalyst for PEM-WE.
58	A Continuous Electrochemical Process to Convert Lignin to Low Molecular Weight Aromatic Compounds and Cogeneration of Hydrogen Naderinasrabadi, Mahtab 02 June 2020 (has links) No description available. Chemical Engineering Engineering Chemistry Wood Sciences Environmental Engineering Lignin electrolysis Hydrogen production Oxygen evolution reaction Lignin depolymerization Lignin conversion GSAM AEM electrolyzer
59	Hydrothermal and Ambient Temperature Anchoring of Co (II) Oxygen Evolution Catalyst on Zeolitic Surfaces Del Pilar Albaladejo, Joselyn January 2014 (has links) No description available. Analytical Chemistry Inorganic Chemistry Materials Science Alternative Energy Chemistry
60	MULTI-FUNCTIONAL CARBON-BASED NANOMATERIALS FOR ENERGY CONVERSION AND STORAGE Dai, Quanbin 25 January 2022 (has links) No description available. Chemistry Materials Science

Search results