Global ETD Search

681	Etude et modélisation de l'interface graphite/électrolyte dans les batteries lithium-ion / Study and establishment of a model of the graphite/electrolyte interface in lithium-ion batteries Chhor, Sarine 19 December 2014 (has links) Cette thèse se positionne dans le domaine des batteries lithium-ion. Elle a pourobjectif de mieux comprendre le fonctionnement de l’électrode négative de graphiteen étudiant le processus de formation du film de passivation, couramment appeléSEI (Solid Electrolyte Interface) créé à l’interface avec l’électrolyte. Ce travail nousa conduit à proposer des modèles pouvant expliquer comment se forme la SEI et àidentifier les phénomènes qui entrent en jeu dans le fonctionnement de la batterie.La SEI résulte de la réaction entre l’électrode de graphite, les ions lithium et les moléculesorganiques de l’électrolyte qui survient lors du premier processus d’insertion.Elle est principalement composée des produits de décomposition de l’électrolyte etles ions lithium consommés ne sont plus échangeables. Elle est donc responsable dela capacité irréversible observée lors du premier cycle de formation, correspondantà la différence de capacité entre le processus d’insertion et le processus de désinsertion.Il est donc essentiel de mieux comprendre les paramètres qui l’influencentpour pouvoir ainsi la contrôler et limiter la perte irréversible de capacité. Les performancesen capacité de l’élément lithium-ion sont directement liées à cette valeurde capacité irréversible, elle doit être limitée afin de maximiser la quantité d’ionslithium échangée entre l’électrode négative et l’électrode positive. La stabilité dela SEI conditionne ensuite le comportement en cyclage de l’électrode au cours dutemps.Dans ce mémoire de thèse, nous avons choisi de caractériser le comportement del’électrode de graphite en faisant varier la nature de l’électrolyte et la taille desparticules de graphite tout en restant le plus proche possible du fonctionnementd’une vraie batterie. Au travers des techniques de caractérisations électrochimiques(cyclage galvanostatique, spectroscopie d’impédance) associées à des techniques decaractérisation de surface (spectroscopie de photoélectrons X, microscopie électroniqueà balayage), les résultats obtenus ont permis de proposer un nouveau modèlede formation de la SEI.Pour l’électrolyte, nous avons choisi de ne regarder que l’effet du solvant (le carbonatede propylène) et de l’additif (le carbonate de vinylène). Ces deux composésentrent dans la composition des électrolytes utilisés dans les éléments lithium-ioncommerciaux. Pour l’électrode de graphite, le choix des particules s’avère primordialpuisque chaque type de particules possède une chimie de surface spécifique (plans223basaux ou plans prismatiques) susceptible de réagir différemment vis-à-vis de l’électrolyte.Deux particules de graphite, de taille et de morphologie différentes, ont étéétudiées. Elles sont utilisées séparément en tant que matière active dans les électrodesnégatives des batteries lithium-ion. Notre spécificité est d’avoir préparé desélectrodes constituées par un mélange de ces deux particules et de les avoir ensuitecaractérisées en formation. L’application de conditions de fonctionnement différentescomme le régime de cyclage et la température d’essai ont mis en évidence les valeursidéales conduisant à minimiser la dégradation de l’électrolyte et à optimiser laqualité du film.Nous avons abouti, au travers de l’ensemble des méthodes de caractérisations misesen oeuvre, à une meilleure compréhension des mécanismes de formation du film depassivation permettant ainsi d’améliorer cette étape essentielle à la pérennité desperformances de l’électrode dans le temps. Ce travail a donc un réel impact auniveau industriel. Le modèle de formation proposé apporte un éclairage nouveau auprocessus de formation et peut permettre également d’aider en amont à la fabricationdes particules de graphite. / This work relates to the lithium ion battery field. The purpose of this study is tobetter understand the behavior of graphite electrodes by focusing on the formationof a passive layer named Solid Electolyte Interface (SEI) which is formed at thegraphite/electrolyte interface. This work has led us to put forward models whichcan explain the SEI formation and identify the reactions which take place in alithium ion battery.The SEI results from reactions between graphite electrode, lithium ions and organicmolecules from the electrolyte during the first charge of the lithium ion battery. It ismainly composed of decomposition products from the electrolyte. Consumed lithiumions can no longer be used in the next cycle. The SEI is therefore responsible for theirreversible capacity during the first formation cycle which is the charge loss betweenthe intercalation process and the deintercalation process. It is necessary to betterunderstand the impact of the formation conditions and other parameters in orderto control and limit the irreversible charge loss. Lithium ion battery performancesdepend on this irreversible capacity, this value has to be reduced in order to maximizethe amount of exchanged lithium ions between negative and positive electrodes. TheSEI stability will determine the electrode behavior upon cycling.In this thesis, we chose to study the graphite behavior by testing several electrolytecompositions and graphite particle sizes in electrochemical cells similar to areal battery. Electrochemical techniques (galvanostatic cycling and electrochemicalimpedance spectroscopy) and surface analyses (X-ray photoelectron spectroscopy,scanning electron microscopy) will be combined. These results helped us to developa new model of the SEI formation.For the electrolyte, we chose to study the effect of the solvent (propylene carbonate)and the additive (vinylene carbonate). Both components are commonly used inthe electrolyte for commercial lithium ion batteries. For the graphite electrode, thechoice of graphite particles is essential because each graphite family has its ownsurface chemistry (basal and prismatic surfaces) which can react in many wayswith the electrolyte. Two graphite particles, with specific sizes and morphologiesare studied. They are separately used as active materials for negative electrodes inlithium ion batteries. Our unique approach is to prepare graphite electrodes basedon a mix of both particles with various compositions and then test the electrode225performances. After testing several formation conditions such as the cycling rateand the temperature, we found the ideal formation conditions for minimizing theelectrolyte decomposition and optimizing the film quality.Finally, based on all the characterization methods, we came to a better understandingof the film formation process. In this way, we have improved this essentialpreliminary step which can now lead to more durable cycling performances overtime. This study can have a major impact on the industrial level. The formationmodel cast a new light on the formation process and can therefore help to makeefficient graphite electrodes. Batteries lithium-ion Formation Film de passivation Interface Electrolyte Solide (SEI) Électrode de graphite Taille de particules Électrolytes à base de carbonates Additifs électrolytiques Spectroscopie de Photoélectrons X (XPS) Lithium-ion batteries Formation Passive layer Solid Electrolyte Interface (SEI) Graphite electrode Particle size Carbonate based electrolytes Electrolyte additives X-ray Photoelectron Spectroscopy (XPS) 620
682	High Capacity Porous Electrode Materials of Li-ion Batteries Penki, Tirupathi Rao January 2014 (has links) (PDF) Lithium-ion battery is attractive for various applications because of its high energy density. The performance of Li-ion battery is influenced by several properties of the electrode materials such as particle size, surface area, ionic and electronic conductivity, etc. Porosity is another important property of the electrode material, which influences the performance. Pores can allow the electrolyte to creep inside the particles and also facilitate volume expansion/contraction arising from intercalation/deintercalation of Li+ ions. Additionally, the rate capability and cycle-life can be enhanced. The following porous electrode materials are investigated. Poorly crystalline porous -MnO2 is synthesized by hydrothermal route from a neutral aqueous solution of KMnO4 at 180 oC and the reaction time of 24 h. On heating, there is a decrease in BET surface area and also a change in morphology from nanopetals to clusters of nanorods. As prepared MnO2 delivers a high discharge specific capacity of 275 mAh g-1 at a specific current of 40 mA g-1 (C/5 rate). Lithium rich manganese oxide (Li2MnO3) is prepared by reverse microemulsion method employing Pluronic acid (P123) as a soft template. It has a well crystalline structure with a broadly distributed mesoporosity but low surface area. However, the sample gains surface area with narrowly distributed mesoporosity and also electrochemical activity after treating in 4 M H2SO4. A discharge capacity of about 160 mAh g-1 is obtained at a discharge current of 30 mA g-1. When the acid-treated sample is heated at 300 °C, the resulting porous sample with a large surface area and dual porosity provides a discharge capacity of 240 mAh g-1 at a discharge current density of 30 mA g-1. Solid solutions of Li2MnO3 and LiMO2 (M=Mn, Ni, Co, Fe and their composites) are more attractive positive electrode materials because of its high capacity >200 mAh g-1.The solid solutions are prepared by microemulsion and polymer template route, which results in porous products. All the solid solution samples exhibit high discharge capacities with high rate capability. Porous flower-like α-Fe2O3 nanostructures is synthesized by ethylene glycol mediated iron alkoxide as an intermediate and heated at different temperatures from 300 to 700 oC. The α-Fe2O3 samples possess porosity with high surface area and deliver discharge capacity values of 1063, 1168, 1183, 1152 and 968 mAh g-1 at a specific current of 50 mA g-1 when prepared at 300, 400, 500, 600 and 700 oC, respectively. Partially exfoliated and reduced graphene oxide (PE-RGO) is prepared by thermal exfoliation of graphite oxide (GO) under normal air atmosphere at 200-500 oC. Discharge capacity values of 771, 832, 1074 and 823 mAh g -1 are obtained with current density of 30 mA g-1 at 1st cycle for PE-RGO samples prepared at 200, 300, 400 and 500 oC, respectively. The electrochemical performance improves on increasing of exfoliation temperature, which is attributed to an increase in surface area. The high rate capability is attributed to porous nature of the material. Results of these studies are presented and discussed in the thesis. Porous Electrode Materials Rechargable Batteries Li-ion Batteries Electrochemical Energy Storage Electrochemical Power Sources Electrode Materials Lithium-ion Batteries Porous MnO2 Porous Li2MnO3 Porous α-Fe2O3 Graphite Oxide (GO) Reduced Graphite Oxide (RGO) Li-ion Cells Graphene Electrochemistry
683	Microstructural and chemical behaviour of irradiated graphite waste under repository conditions Hagos, Bereket Abrha January 2013 (has links) A procedure to evaluate the leaching properties of radionuclides from irradiated graphite waste has been developed by combining ANSI 16.1 (USA) and NEN 7345 (Netherlands) standardised diffusion leaching techniques. The ANSI 16.1 standard has been followed to the acquire the leachates and to determine the leach rate/ diffusion coefficient and NEN 7345 standard technique has been used to determine the diffusion mechanism of radionuclides. The investigation employs simulated Drigg groundwater as a leachant using semi-dynamic technique for the production of leachate specimens. From gamma spectroscopy analysis the principal radionuclides present in terms of activity were 60Co, 137Cs, 134Cs, 155Eu, 133Ba and 46Sc. The dominant radionuclides are 60Co, 134Cs and 133Ba which together account for about 91 % of the total activity. The 91 % can be broken down into 73.4 % 60Co, 9.1 % 134Cs and 8.1 % 133Ba. Analysis of total beta and total beta without tritium activity release from Magnox graphite was measured using liquid scintillating counting. Preliminary results show that there is an initial high release of activity and decreases when the leaching period increases. This may be due to the depletion of contaminants which were absorbed by the internal pore networks and the surface. During the leaching test approximately 275.33 ± 18.20 Bq of 3H and 106.26 ± 7.01 Bq of 14C was released into the leachant within 91 days. Irradiation induced damages to the nuclear graphite crystal structure have been shown to cause disruption of the bonding across the basal planes. Moreover, the closures of Mrozowski cracks have been observed in nuclear graphite, the bulk property are governed by the porosity, in particular, at the nanometre scale. Therefore, knowledge of the crystallite structure and porosity distribution is very important; as it will assist in understand the affects of irradiated damage and location and the mechanism of the leaching of radionuclides. The work reported herein contributed several key findings to the international work on graphite leaching to offer guidance leading toward obtaining leaching data in the future: (a) the effective diffusion coefficient for 14C from graphite waste has been determined. The diffusion process for 14C has two stages resulting two different values of diffusion coefficient, i.e., for the fast and slow components; (b) the controlling leaching mechanism for 3H radionuclide from graphite is shown to be surface wash–off; and for that of 14C radionuclide the initial controlling leaching mechanism is surface wash-off following by diffusion which is the major transport mechanism ; (c) The weight loss originates from the open pore structure which has been opened up by radiolytic oxidation; at the higher weight losses much of the closed porosity in the graphite has been opened. The investigation indicates that weigh loss has a major influence on the leaching of elements from the irradiated graphite; and (d) the analysis of the pores in nuclear graphite can be categorised into three types. These three types of pores are: (1) small pores narrow which are slit-shaped pores in the binder phase or matrix, (2) gas evolution pores or gas entrapment pores within the binder phase or matrix and (3) lenticular pores which are large cracks within the filler particles. It is shown in this thesis that by using tomography to study the morphology of the different pores coupled with the distribution of impurities an understanding of the role of porosity in leaching is possible. 620.1
684	Studie zefektivnění přípravy výroby u vybrané technologie / The study of increase in efficiency of manufacturing preparation of technology Šudoma, Michal January 2009 (has links) This paper discusses different alternatives of more efficient preparation of spheroided graphite cast iron production. Secondary metallurgy and chemical heating technology are used to recast cast iron fused in copula furnace. The work applies the known physical-chemical rules used in the production of quality spheroided graphite cast iron in regular production conditions. Based on the previous developments, the aim was to prepare implementation of verified secondary metallurgy processes in adjusted casting ladle. The casting ladle was adjusted in order to allow execution of all processes required in order for the relevant standards and material lists requirements to be met in respect to spheroided graphite cast iron quality. Comments regarding the trends in ferroalloy metallurgy and related marketing approach of the company. The work is concluded by a summary of advantages brought in by the new approaches compared to the traditional ones from the economical as well as environmental perspective.
685	Material analysis for a rotating inlet valve : Sliding contact in an oil-free super-critical steam environment / Materialanalys för en roterande inloppsventil : Glidande kontakt i en oljefri superkritisk ångmiljö Samuelsson, Johan January 2022 (has links) In this thesis, the aim is to study possible tribo-materials for a rotating inlet valve and to find a suitable material combination for the contact. The valve is part of a modern oil-free and high temperature steam engine. Systematic material selection together with tribological tests and wear analyses are performed. The metals Nitronic 60 and Stellite 6B are tested as self-mated metals, and run against graphite. None of these combinations are found suitable. However, the tests show carbon-based materials to be promising. After further study another carbon-based material, antimony impregnated mechanical carbon is selected as valve seat. For the mating part valve distributor, the material ZrO2-MgO is selected. This tribo-pair has shown friction and wear in the same interval as oil-lubrication. The friction and wear are 50% respectively 10% of the second best tribo-pair found in this thesis. The valve seat material is realizable if supported by a valve block of a Ni-resist cast iron with thermal expansion similar to the valve seat. Lastly a redesign of the valve distributor is suggested to comply with ceramic design guidelines. / Målet med denna rapport är att studera möjliga tribo-material för en roterande inloppsventil och att hitta en lämplig materialkombination för kontakten. Ventilen är en del av en modern oljefri och högtempererad ångmotor. Ett systematiskt materialval tillsammans med tribologiska tester och nötningsanalyser utförs. Metallerna Nitronic 60 och Stellite 6B testas dels mot sig själva, och dels mot grafit. Ingen av dessa kombinationer finns lämplig. Testerna visar dock att kolbaserade material är lovande och eftervidare studier är ett annat kolbaserat material, antimonimpregnerat mekaniskt kol, väljs till ventilsätet. Till motytan till ventilsätet, ventilfördelaren, väljs materialet ZrO2-MgO. Detta tribo-par har visat friktion och nötning i samma intervall som oljesmörjning. Friktionen och nötningen är 50 % respektive 10 % av det näst bästa tribo-paret som hittats i denna avhandling. Ventilsätets material är realiserbart om det stöttas i ett ventilblock av ett ”Ni-resist” gjutjärn med en värmeexpansion som liknar ventilsätets. Slutligen föreslås en omkonstruktion av ventilfördelaren för att uppfylla riktlinjerna för keramisk konstruktion. Mechanical carbon graphite carbon graphite zirconia steam engine steam tribology friction wear stellite nitronic 60 antimony carbon Ni-resist cast iron waste heat recovery rotating inlet valve valve Mekaniskt kol gafit ångmotor ånga tribologi friktion nötning gjutjärn roterande inloppsventil ventil
686	Recyclage du carbone et formation du diamant en zone de subduction : contraintes expérimentales Martin, Audrey 23 January 2009 (has links) (PDF) Afin d'évaluer les hypothèses de recyclage interne du carbone par la subduction et de formation de diamant dans la croûte subductée, des expériences ont été réalisées en presse multi-enclumes sur l'assemblage Fe-dolomite + quartz (présent dans les sédiments subductés ou formé par l'altération des basaltes) dans des conditions de pression-température de 4 à 14 GPa et de 800 à 1600°C. Deux études ont été menées : la stabilité de cet assemblage a d'abord été testée en conditions rédox intrinsèques puis en conditions réductrices ; ensuite, les interactions avec le coin mantellique ont été évaluées en étudiant, d'une part, les processus d'échange entre un cylindre de Fe-dolomite + quartz et un cylindre de péridotite à grenat, et d'autre part, les équilibres de phases dans des mélanges péridotite-sédiment. Cette étude montre qu'un sédiment (ou une éclogite) carbonaté est déstabilisé à plus faible profondeur en présence de fer. De plus, les conditions réductrices imposées par le manteau diminuent encore la stabilité de cet assemblage lors de la subduction. Une zone réactionnelle à clinopyroxène + Fe-magnésite se forme à l'interface slab/manteau. L'infiltration du carbone dans le coin mantellique est très rapide et de la magnésite s'y forme. Ainsi, un recyclage des carbonates à grande profondeur semble peu probable. Ces expériences montrent également que du graphite ou du diamant peut se former au sommet de la croûte océanique subductée par réduction des carbonates à basse température. Subduction Thèses et écrits académiques Carbone Thèses et écrits académiques Dolomie Thèses et écrits académiques Quartz Thèses et écrits académiques Basalte Graphite Diamant
687	Stratégie analytique des tradimédicaments : établissement de profils chromatographiques des métabolites phytochimiques apolaires Bony, Nicaise françois 26 September 2013 (has links) (PDF) Les médicaments traditionnels à base de plantes (tradimédicaments) sont très utilisés par les populations africaines. Mais leur qualité est difficile à maîtriser, car ce sont des mélanges complexes de plusieurs drogues végétales ou des préparations à base de drogues végétales d'origine souvent inconnue et/ou très variable. Le profil chromatographique des métabolites phytochimiques constitue un outil important pour l'évaluation de la qualité de ces produits.L'objectif de ce travail est de proposer un protocole de préparation des échantillons et d'établissement de profil par chromatographie liquide et chromatographie en phase gazeuse des métabolites apolaires, pour l'évaluation de la qualité des médicaments traditionnels à base de plantes.La méthodologie est basée sur le traitement chimiométrique des profils chromatographiques des métabolites apolaires issus de différents lots de feuilles de Combretum micranthum et Mitracarpus scaber.Le profilage métabolique s'est effectué par chromatographie liquide sur Carbone Graphite Poreux en milieu non-aqueux et par chromatographie en phase gazeuse à haute température, couplées à la spectrométrie de masse, après extraction au dichlorométhane et élimination de la chlorophylle adsorbée sur charbon actif.L'analyse chimiométrique des données utilisant l'analyse PLS-discriminante avec ou sans correction orthogonale du signal, appliquée aux profils chromatographiques des feuilles de Combretum micranthum et Mitracarpus scaber, a montré de faibles différences entre les lots de chaque drogue végétale, et une différenciation claire des deux drogues végétales.Les deux méthodes d'analyse par chromatographie liquide et chromatographie en phase gazeuse permettent de détecter la plupart des métabolites secondaires apolaires bioactifs ou non déjà identifiés dans les feuilles des deux espèces. [CHIM:OTHE] Chemical Sciences/Other [CHIM:OTHE] Chimie/Autre Carbone Graphite Poreux Métabolites apolaires Chimiométrie Combretum micranthum Mitracarpus scaber
688	On the physisorption of water on graphene: a CCSD(T) study Voloshina, Elena, Usvyat, Denis, Schütz, Martin, Dedkov, Yuriy, Paulus, Beate 02 April 2014 (has links) (PDF) The electronic structure of the zero-gap two-dimensional graphene has a charge neutrality point exactly at the Fermi level that limits the practical application of this material. There are several ways to modify the Fermi-level-region of graphene, e.g. adsorption of graphene on different substrates or different molecules on its surface. In all cases the so-called dispersion or van der Waals interactions can play a crucial role in the mechanism, which describes the modification of electronic structure of graphene. The adsorption of water on graphene is not very accurately reproduced in the standard density functional theory (DFT) calculations and highly-accurate quantum-chemical treatments are required. A possibility to apply wavefunction-based methods to extended systems is the use of local correlation schemes. The adsorption energies obtained in the present work by means of CCSD(T) are much higher in magnitude than the values calculated with standard DFT functional although they agree that physisorption is observed. The obtained results are compared with the values available in the literature for binding of water on the graphene-like substrates. / Dieser Beitrag ist mit Zustimmung des Rechteinhabers aufgrund einer (DFG-geförderten) Allianz- bzw. Nationallizenz frei zugänglich. Elektronenkorrelation Wannier-Darstellung Physisorption Graphen Graphit Kohlenstoff-Nanoröhrchen Dichtefunktionaltheorie electron correlation methods localized wannier functions gaussian-basis sets ab-initio density functionals triple excitations molecular-dynamics correlation-energy carbon nanotubes graphite ddc:540 rvk:VA 1120
689	An Experimental Study of Submerged Entry Nozzles (SEN) Focusing on Decarburization and Clogging Memarpour, Arashk January 2011 (has links) The submerged entry nozzle (SEN) is used to transport the molten steel from a tundish to a mould. The main purpose of its usage is to prevent oxygen and nitrogen pick-up by molten steel from the gas. Furthermore, to achieve the desired flow conditions in the mould. Therefore, the SEN can be considered as a vital factor for a stable casting process and the steel quality. In addition, the steelmaking processes occur at high temperatures around 1873 K, so the interaction between the refractory materials of the SEN and molten steel is unavoidable. Therefore, the knowledge of the SEN behaviors during preheating and casting processes is necessary for the design of the steelmaking processes The internal surfaces of modern SENs are coated with a glass/silicon powder layer to prevent the SEN graphite oxidation during preheating. The effects of the interaction between the coating layer and the SEN base refractory materials on clogging were studied. A large number of accretion samples formed inside alumina-graphite clogged SENs were examined using FEG-SEM-EDS and Feature analysis. The internal coated SENs were used for continuous casting of stainless steel grades alloyed with Rare Earth Metals (REM). The post-mortem study results clearly revealed the formation of a multi-layer accretion. A harmful effect of the SENs decarburization on the accretion thickness was also indicated. In addition, the results indicated a penetration of the formed alkaline-rich glaze into the alumina-graphite base refractory. More specifically, the alkaline-rich glaze reacts with graphite to form a carbon monoxide gas. Thereafter, dissociation of CO at the interface between SEN and molten metal takes place. This leads to reoxidation of dissolved alloying elements such as REM (Rare Earth Metal). This reoxidation forms the “In Situ” REM oxides at the interface between the SEN and the REM alloyed molten steel. Also, the interaction of the penetrated glaze with alumina in the SEN base refractory materials leads to the formation of a high-viscous alumina-rich glaze during the SEN preheating process. This, in turn, creates a very uneven surface at the SEN internal surface. Furthermore, these uneven areas react with dissolved REM in molten steel to form REM aluminates, REM silicates and REM alumina-silicates. The formation of the large “in-situ” REM oxides and the reaction of the REM alloying elements with the previously mentioned SEN´s uneven areas may provide a large REM-rich surface in contact with the primary inclusions in molten steel. This may facilitate the attraction and agglomeration of the primary REM oxide inclusions on the SEN internal surface and thereafter the clogging. The study revealed the disadvantages of the glass/silicon powder coating applications and the SEN decarburization. The decarburization behaviors of Al2O3-C, ZrO2-C and MgO-C refractory materials from a commercial Submerged Entry Nozzle (SEN), were also investigated for different gas atmospheres consisting of CO2, O2 and Ar. The gas ratio values were kept the same as it is in a propane combustion flue gas at different Air-Fuel-Ratio (AFR) values for both Air-Fuel and Oxygen-Fuel combustion systems. Laboratory experiments were carried out under nonisothermal conditions followed by isothermal heating. The decarburization ratio (α) values of all three refractory types were determined by measuring the real time weight losses of the samples. The results showed the higher decarburization ratio (α) values increasing for MgO-C refractory when changing the Air-Fuel combustion to Oxygen-Fuel combustion at the same AFR value. It substantiates the SEN preheating advantage at higher temperatures for shorter holding times compared to heating at lower temperatures during longer holding times for Al2O3-C samples. Diffusion models were proposed for estimation of the decarburization rate of an Al2O3-C refractory in the SEN. Two different methods were studied to prevent the SEN decarburization during preheating: The effect of an ZrSi2 antioxidant and the coexistence of an antioxidant additive and a (4B2O3 ·BaO) glass powder on carbon oxidation for non-isothermal and isothermal heating conditions in a controlled atmosphere. The coexistence of 8 wt% ZrSi2 and 15 wt% (4B2O3 ·BaO) glass powder of the total alumina-graphite refractory base materials, presented the most effective resistance to carbon oxidation. The 121% volume expansion due to the Zircon formation during heating and filling up the open pores by a (4B2O3 ·BaO) glaze during the green body sintering led to an excellent carbon oxidation resistance. The effects of the plasma spray-PVD coating of the Yttria Stabilized Zirconia (YSZ) powder on the carbon oxidation of the Al2O3-C coated samples were investigated. Trials were performed at non-isothermal heating conditions in a controlled atmosphere. Also, the applied temperature profile for the laboratory trials were defined based on the industrial preheating trials. The controlled atmospheres consisted of CO2, O2 and Ar. The thicknesses of the decarburized layers were measured and examined using light optic microscopy, FEG-SEM and EDS. A 250-290 μm YSZ coating is suggested to be an appropriate coating, as it provides both an even surface as well as prevention of the decarburization even during heating in air. In addition, the interactions between the YSZ coated alumina-graphite refractory base materials in contact with a cerium alloyed molten stainless steel were surveyed. The YSZ coating provided a total prevention of the alumina reduction by cerium. Therefore, the prevention of the first clogging product formed on the surface of the SEN refractory base materials. Therefore, the YSZ plasma-PVD coating can be recommended for coating of the hot surface of the commercial SENs. / <p>QC 20111014</p> Refractory SEN Clogging REM Coating glaze alkaline Post- Mortem industrial preheating ZrSi2 Graphite Alumina Oxidation Al2O3-C ZrO2-C MgO-C decarburization reaction mechanism Yttria Stabilized Zirconia plasma spray-PVD coating
690	Voltametrické stanovení vybraných psychofarmak pomocí uhlíkových elektrod / Voltammetric Determination of Selected Psychopharmaceuticals Using Carbon Electrodes Matouš, Petr January 2019 (has links) Differential pulse voltammetry (DPV) was used for developing a method for the determination of phenothiazine derivatives, namely chlorpromazine (CHP) and levomepromazine (LMP), using a glassy carbon electrode (GCE) and a graphite electrode, both with a 2 mm disc diameter. Comparison of quantification limits (LQ) for both substances on both electrodes was performed. After optimizing and processing the results, the optimal conditions for measuring calibrations were as follows: Britton- Robinson (BR) buffer at pH 4.0. Calibration dependences were measured inthe concentration range from 1·10-7 to 1·10-4 mol·dm-3 . There was no need for electrochemical electrode regeneration or matrix pretreatment. The results showed higher measurement sensitivity for CHP, and the graphite electrode also showed higher sensitivity. Although there were measured lower concentrations with the graphite electrode in comparison to the GCE, because of the low repeatability of the measurements in the lower concentration range 1-10·10-7 mol·dm-3 , the LQ is comparable to the results reached on the GCE. Besides to the BR buffer, measurements in other matrices (drinking water and river water) were also made. The following LQ values were achieved: 1.0·10-6 mol·dm-3 (in BR buffer), 1.1·10-6 -1.4·10-6 mol·dm-3 (in drinking water) and...

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