Equilibres de phases et microstructures d'alliages CU-FE-NI riches en FE / Design of a new iron-nickel-copper binder for diamond tools

Crozet, Coraline

28 January 2011

Ce travail a pour but l’acquisition de connaissances fondamentales dans les équilibres de phases et les transformations de phases des alliages ternaires contenant du fer, du nickel et du cuivre.Cette étude est composée de trois parties : la première est consacrée aux équilibres de phase entre600°C et 1000°C dans le coin riche en fer du système ternaire Cu-Fe-Ni, la seconde concerne l’analyse des transformations de phases dans des alliages modèles suivant deux vitesses de refroidissement et la troisième étudie les alliages industriels.Cette approche expérimentale est appuyée par des calculs thermodynamiques. Une comparaison est effectuée avec les données issues de la littérature. Les sections isothermes à 600°C, 800°C et1000°C ont été reconfirmées. Les domaines triphasés αFe/γFe/γCu ont été déterminés à 600°C et800°C et semblent décalés vers de plus fortes teneurs en Ni. La lacune de miscibilité est moins étendue que celle calculée et ce particulièrement du côté du binaire Cu-Ni.Les transformations de phase γ→α apparaissant lors du refroidissement d’alliages Fe-xCu-10Ni et Fe-10Cu-xNi (0<x<15 % en masse) ont été étudiées. Elles sont observées dans tous les alliages refroidis lentement par dilatométrie sauf dans l’alliage binaire Fe-Cu. Les températures de transformation sont systématiquement inférieures aux températures d’équilibre et cet écart augmente lorsque les teneurs en Ni et Cu augmentent. La formation de la ferrite bainitique est favorisée par l’addition de Cu dans les alliages trempés Fe-xCu-10Ni et par l’addition de Ni dans les alliages Fe-10Cu-xNi tandis que la ferrite massive se forme préférentiellement lors du refroidissement lent. Une diminution des températures de transformation se produit lorsque la taille de grains est affinée et est reliée au processus d’accommodation plastique liée à la transformation.La composition et la vitesse de refroidissement jouent un rôle sur la dureté de ces alliages via la présence de Ni en solution solide ainsi que le nombre et la taille des précipités de Cu. / This work aims in getting fundamental knowledge of phase equilibria and microstructures of ternary alloys containing copper, nickel and iron. The thesis is composed of three parts: a first part is devoted to phase equilibria in the Fe-rich corner of the ternary Cu-Fe-Ni system between 600°C and 1000°C, a second part is devoted to the microstructures in these materials for model alloys, for two cooling rates and a third part is devoted to industrial alloys.Phase equilibria of the system are investigated in the range 600-1000°C using diffusion multiples in conjunction with selected equilibrated alloys. This experimental approach is supplemented by thermodynamic calculations. A comparison is drawn with data reported in the literature. The isothermal sections at 600°C, 800°C and 1000°C have been reconfirmed. The three-phase regions αFe/γFe/γCu are determined at 600°C and 800°C and appear shifted to a higher Ni content. The miscibility gap is narrower than the calculated, particularly on the Cu-Ni binary sides.Austenite/ferrite phase transformations occurring on cooling in Fe-xCu-10Ni and Fe-10Cu-xNi alloys,0<x<15 (mass%), have been studied. The influence of copper and nickel additions and of the cooling rate on the microstructure is discussed. Metastable transformations in slowly cooled alloys have been detected by dilatometry in all alloys except in the binary Fe-10Cu alloy: all the cooling transformation temperatures are systematically lower than the equilibrium temperature and the Ni and Cu addition decrease this transformation temperature. The formation of bainitic ferrite is favoured by copper additions in quenched Fe-xCu-10Ni alloys and by Ni addition in Fe-10Cu-xNi alloys while massive ferrite form preferentially during slow cooling. A decrease of the transformation temperatures is recorded when the alloys have a finer grain size likely related to plastic accommodation processes.The composition and cooling rate influence the hardness of the alloys mostly dependant on the amount of Ni in solid solution and on the rate and size of Cu precipitates.

Thermodynamique

Transformation de phase

Alliages Fe-Ni-Cu

Thermodynamic

Phase transformations

Fe-Ni-Cu alloys

VLE measurements of ether alcohol blends for investigation on reformulated gasoline

Benecke, Travis Pio

January 2016

Submitted in fulfillment of the requirements of the degree of Master of Engineering, Durban University of Technology, Durban, South Africa, 2016. / Separation processes in the chemical process industries is dependent on the science of chemical thermodynamics. In the field of chemical separation process engineering, phase equilibrium is a primary area of interest. This is due to separation processes such as distillation and extraction which involves the contacting of different phases for effective separation. The focal point of this research project is the measurement and modeling of binary vapour-liquid equilibrium (VLE) phase data of systems containing ether-alcohol organic compounds. The VLE data were measured with the use of the modified apparatus of Raal and Mühlbauer, (1998). The systems of interest for this research arose from an industrial demand for VLE data for systems containing ether-alcohol organic compounds. This gave rise to the experimental VLE data isotherms being measured for the following binary systems: a) Methyl tert-butyl ether (1) + 1-pentanol (2) at 317.15 and 327.15 K b) Methyl tert-butyl ether (1) + 2, 2, 4-trimethylpentane (2) at 307.15, 317.15 and 327.15K c) 2, 2, 4-Trimethylpentane (1) + 1-pentanol (2) at 350.15, 360.15 and 370.15K d) Diisopropyl ether (1) + 2,2,4-trimethylpentane (2) at 320.15, 330.15 and 340.15K e) Diisopropyl ether (1) + 1-propanol (2) at 320.15, 330.15 and 340.15K f) Diisopropyl ether (1) + 2-butanol (2) at 320.15, 330.15 and 340.15K The data for all the measured binary systems investigated at these temperatures are currently not available in the open source literature found on the internet and in library text resources. The systems were not measured at the same temperatures because certain system isotherm temperatures correlate to a pressures above 1 bar. This pressure of 1 bar is the maximum operating pressure specification of the VLE apparatus used in this project. The experimental VLE data were correlated for model parameters for both the  and methods. For the method, the fugacity coefficients (vapour-phase non-idealities) were tabulated using the virial equation of state and the Hayden-O’Connell correlation (1975); chemical theory and the Nothnagel et al. (1973) correlation method. The activity coefficients (liquid phase non-idealities) were calculated using three local-composition based activity coefficients models: the Wilson (1964) model, the NRTL model (Renon and Prausnitz, 1968); and the UNIQUAC model (Abrams and Prausnitz, 1975). Regarding the direct method, the Soave-Redlich-Kwong (Redlich and Kwong, 1949) and Peng-Robinson (1976) equations of state ii were used with the temperature dependent alpha-function (α) of Mathias and Copeman (1983) with the Wong-Sandler (1992) mixing rule. Thermodynamic consistency testing, which presents an indication of the quality and reliability of the data, was also performed for all the experimental VLE data. All the systems measured showed good thermodynamic consistency for the point test of Van Ness et al. (1973) - the consistency test of choice for this research. This however, was based on the model chosen for the data regression of a particular system. Therefore, the combined method of VLE reduction produced the most favourable results for the NRTL and Wilson models. / M

Chemical engineering

Vapor-liquid equilibrium

Ethers

Alcohols

Separation (Technology)

Reformulated gasoline

Thermodynamic equilibrium

The Arctic Atmosphere : Interactions between clouds, boundary-layer turbulence and large-scale circulation

Sotiropoulou, Georgia

January 2016

Arctic climate is changing fast, but weather forecast and climate models have serious deficiencies in representing the Arctic atmosphere, because of the special conditions that occur in this region. The cold ice surface and the advection of warm air aloft from the south result in a semi-continuous presence of a temperature inversion, known as the “Arctic inversion”, which is governed by interacting large-scale and local processes, such as surface fluxes and cloud formation. In this thesis these poorly understood interactions are investigated using observations from field campaigns on the Swedish icebreaker Oden: The Arctic Summer Cloud Ocean Study (ASCOS) in 2008 and the Arctic Clouds in Summer Experiment (ACSE) in 2014. Two numerical models are also used to explore these data: the IFS global weather forecast model from the European Center for Medium-range Weather Forecasts and the MIMICA LES from Stockholm University. Arctic clouds can persist for a long time, days to weeks, and are usually mixed-phase; a difficult to model mixture of super-cooled cloud droplets and ice crystals. Their persistence has been attributed to several mechanisms, such as large-scale advection, surface evaporation and microphysical processes. ASCOS observations indicate that these clouds are most frequently decoupled from the surface; hence, surface evaporation plays a minor role. The determining factor for cloud-surface decoupling is the altitude of the clouds. Turbulent mixing is generated in the cloud layer, forced by cloud-top radiative cooling, but with a high cloud this cannot penetrate down to the surface mixed layer, which is forced primarily by mechanical turbulence. A special category of clouds is also found: optically thin liquid-only clouds with stable stratification, hence insignificant in-cloud mixing, which occur in low-aerosol conditions. IFS model fails to reproduce the cloud-surface decoupling observed during ASCOS. A new prognostic cloud physics scheme in IFS improves simulation of mixed-phase clouds, but does not improve the warm bias in the model, mostly because IFS fails to disperse low surface-warming clouds when observations indicate cloud-free conditions. With increasing summer open-water areas in a warming Arctic, there is a growing interest in processes related to the ice marginal zones and the summer-to-autumn seasonal transition. ACSE included measurements over both open-water and sea-ice surfaces, during melt and early freeze. The seasonal transition was abrupt, not gradual as would have been expected if it was primarily driven by the gradual changes in net solar radiation. After the transition, the ocean surface remained warmer than the atmosphere, enhancing surface cooling and facilitating sea-ice formation. Observations in melt season showed distinct differences in atmospheric structure between the two surface types; during freeze-up these largely disappear. In summer, large-scale advection of warm and moist air over melting sea ice had large impacts on atmospheric stability and the surface. This is explored with an LES; results indicate that while vertical structure of the lowest atmosphere is primarily sensitive to heat advection, cloud formation, which is of great importance to the surface energy budget, is primarily sensitive to moisture advection. / <p>At the time of the doctoral defense, the following paper was unpublished and had a status as follows: Paper 4: Manuscript.</p>

Arctic

mixed-phase clouds

thermodynamic structure

Arctic inversion

cloud-surface interactions

seasonal transition

IFS model

LES

Investigation of vanadium-containing oxide systems : CALPHAD and experiments

Yang, Yang

January 2016

Fundamental studies on thermodynamic properties of vanadium-containing oxides systems are essential to understand practical vanadium metallurgical process. The CALPHAD technique is here applied to the thermodynamic modelling of the V-O, Ca-V-O and Ti-V-O systems. The compound energy formalism is used for all the solution phases. All optimization processes and calculations are performed using the Thermo-Calc software package. The present work attempts to develop a self-consistent thermodynamic database of all phases in the studied systems. The obtained datasets can be used to calculate thermodynamic properties, stable as well as metastable phase equilibria and driving forces for oxidation etc. Steelmaking slag is an important secondary source for vanadium extraction. The phase relationships and vanadium distribution in the CaO-SiO2-MgO-V2O3-Al2O3 synthetic slags, whose compositions were chosen based on the relevance to the steel producers, are also studied. Phase equilibria in the temperature range of 1773 to 1823 K at oxygen partial pressure of 10-10 bar and 0.21 bar were characterized. An investigation of the volatilization of vanadium oxide was also carried out in the present work. Isothermal evaporation of vanadium pentoxide in the temperature range between 1723 and 1873 K was investigated by Thermogravimetric Analysis under different oxygen partial pressures, viz. oxygen, air or CO2. The Arrhenius activation energy for the evaporation reaction in various atmospheres was calculated from the experimental results. A mathematical model was developed to describe the kinetics of the evaporation process. Evaporation coefficients and enthalpies in various atmospheres were also estimated. The present results may have some implications in recovering vanadium from different vanadium-bearing sources. / <p>QC 20161202</p>

activation energy

TGA

activity

Thermodynamic vs kinetic control of particle assembly and pattern replication

Chen, Lizhen

01 January 2017

This research aims to investigate how particles assemble together through thermodynamic and kinetic control. Particle assembly with thermodynamic control is achieved in part due to electrostatic attraction between particles. Electrostatic attraction between particles can be achieved by functionalizing polystyrene or SiO2 particles with different charges. Particles with different charges will come together in solution slowly and self-assemble to form ordered crystals with different patterns based on size and charge ratios of two oppositely charged particles. Kinetic control of particle assembly is achieved by pattern aided exponential amplification of nanoscale structures. Some of these nanoscale structures are difficult to build with other conventional synthetic methods. On the other hand, as for kinetically controlled particle replication, the patterns can be synthesized by one of two ways i) crystal products which are produced by thermodynamically controlled particle assembly or ii) single particle deposition. Specifically, kinetically controlled particle assembly focuses on constructing SiO2 particles. Exponential replication of SiO2 particles is achieved by growing a "bridge layer", between templates of SiO2 particles and next generation SiO2 replicas. By dissolving the bridge layer, two times the amount of the SiO2 particles with the shape of the original templates can be formed. In the next generation, all the particles serve as template particles. Thus, after n cycles of replication, 2n amount of products can be formed. If successful, particle assembly can be thermodynamic controlled and particle exponential replication can be kinetical controlled, which will enable new ways to build particles with well-defined shapes from readily available building blocks.

Exponential replication

Particle assembly

Pattern growth

SiO2

Thermodynamic and kinetic control

Well-defined shape

Chemistry

Etude du captage du CO2 par la cristallisation des hydrates de gaz : Application au mélange CO2-N2 / CO2 capture by gaz hydrate cristallization : Application on the CO2-N2 mixture

Bouchemoua, Amina

16 July 2012

Le captage du CO2 représente un enjeu industriel majeur et scientifique du siècle. Il existe différentes méthodes de séparation et de captage du CO2, telles que, l'absorption aux amines et l’adsorption. Bien que ces processus soient bien développés au niveau industriel, ils sont très consommateurs d’énergie. Le procédé de captage du CO2 par formation d’hydrates de gaz consomme moins d’énergie et semble être très prometteur pour la séparation du CO2 Les hydrates de gaz sont des composés cristallins de la famille des clathrates dans lesquels des molécules d'eau se relient entre elles par des liaisons hydrogène pour former des cavités qui peuvent contenir des molécules de gaz. La formation d'hydrates de gaz est favorisée par une haute pression et basse température.Cette étude est menée dans le cadre du projet ANR SECOHYA. L'objectif est d'étudier les conditions thermodynamiques et cinétiques du procédé de captage du CO2 par cristallisation d'hydrates de gaz.Premièrement, nous avons développé un dispositif expérimental pour réaliser des expériences afin de déterminer les conditions thermodynamiques et cinétiques de formation des hydrates mixtes CO2-N2 dans l'eau comme phase liquide. Nous avons montré que la pression opératoire peut être très élevée et la température très basse. Pour la faisabilité du projet, nous avons utilisé le TBAB (TétraButylAmmonium Bromure) en tant qu'additif thermodynamique dans la phase liquide. L'utilisation du TBAB peut réduire considérablement la pression opératoire.Dans la deuxième partie de cette étude, nous avons présenté un modèle thermodynamique, basé sur le modèle de van der Waals et Platteeuw. Ce modèle permet de prédire les conditions d'équilibre thermodynamique de formation des hydrates de gaz. Des données expérimentales d'équilibre de mélanges CO2-CH4 et de CO2-N2 sont présentées et comparées à des résultats théoriques. / CO2 capture and sequestration represent a major industrial and scientific challenge of thiscentury. There are different methods of CO2 separation and capture, such as solid adsorption, amines adsorption and cryogenic fractionation. Although these processes are welldeveloped at industrial level, they are energy intensive. Hydrate formation method is a lessenergy intensive and has an interesting potential to separate carbon dioxide. Gas hydrates are Document crystalline compounds that consist of hydrogen bonded network of water molecules trapping a gas molecule. Gas hydrate formation is favored by high pressure and low temperature. This study was conducted as a part of the SECOHYA ANR Project. The objective is to study the thermodynamic and kinetic conditions of the process to capture CO2 by gas hydrate crystallization. Firstly, we developed an experimental apparatus to carry out experiments to determine the thermodynamic and kinetic formation conditions of CO2-N2 gas hydrate mixture in water as liquid phase. We showed that the operative pressure may be very important and the temperature very low. For the feasibility of the project, we used TBAB (TetraButylAmmonium Bromide) as thermodynamic additive in the liquid phase. The use of TBAB may reduce considerably the operative pressure.In the second part of this study, we presented a thermodynamic model, based on the van der Waals and Platteeuw model. This model allows the estimation of thermodynamic equilibrium conditions. Experimental equilibrium data of CO2-CH4 and CO2-N2 mixtures are presented and compared to theoretical results.

Hydrate

Cristallisation

Thermodynamique

CO2

TBAB

Modélisation

Hydrate

Crystallization

Thermodynamic

CO2

TBAB

Modeling

665.7

Les origines de l'hystérésis de potentiel dans les batteries Li-ion / The origin of voltage hysteresis in Li-ion batteries

Khatib, Rémi

05 April 2013

Dans les années 2000, les matériaux de conversion sont apparus comme une alternative intéressante aux matériaux d'insertion actuellement utilisés dans les batteries Li-ion. Ils réagissent avec le lithium pour former une électrode constituée de nanoparticules métalliques encapsulées dans une matrice lithiée. Pour comprendre ces réactions, le phosphure de cobalt (CoP) a été étudié au moyen de techniques théoriques et expérimentales. La complexité de ces systèmes nanocomposites n'a pas permis de caractériser toutes les espèces présentes dans l'électrode. Cependant, les calculs DFT ont prédit la formation de composés intermédiaires dont les potentiels de formation sont cohérents avec l'expérience. De plus, ces travaux ont mis en évidence l'importance de la réactivité de surface quant à l'origine de l'hystérésis de potentiel qui nuit au rendement énergétique de ce type d'électrode. La méthodologie développée spécialement pour les réactions de conversion, mais transférable vers d'autres réaction électrochimique, a été validée par les mesures expérimentales. / In the 2000s, conversion materials appeared as an interesting alternative to the insertion materials currently used in Li-ion batteries. They react with lithium to form an electrode constituted of metallic nanoparticles embedded into a lithiated matrix. To understand those reactions, cobalt phosphide (CoP) has been studied by theoretical and experimental techniques. The complexity of those nanocomposite systems does not allow to characterize all the species present inside the electrode. However, DFT calculations predicted the formation of intermediate compounds whose the formation potentials are in agreement with the experiment. Moreover, these studies have highlighted the importance of surface reactivity about the voltage hysteresis which harms to the electrode efficiency.The methodology especially developed for conversion reactions, but transferable to others electrochemical reaction, was validated by experimental measures.

Hystérésis

Lithium

Polarisation

Interfaces

Structure électronique

Thermodynamique

Hysteresis

Lithium

Polarisation

Interface

Electronical structure

Thermodynamic

Experimental determination and thermodynamic modelisation of Mo-Ni-Re system / Détermination expérimentale et modélisation thermodynamique du système Mo-Ni-Re

Yaqoob, Khurram

20 December 2012

E système Mo-Ni-Re est un sous-système majeur des superalliages à base de Ni conçus pour une utilisation dans les applications à haute température. Compte tenu des contradictions entre les informations publiées antérieurement, cette étude a été consacrée à la détermination expérimentale complète des équilibres entre phases dans le système Mo-Ni-Re, à la caractérisation structurale des phases intermétalliques et à la modélisation thermodynamique du système à l'aide de la méthode CALPHAD. L'étude expérimentale des équilibres entre phases a été effectuée en utilisant des alliages à l'équilibre, et les diagrammes de phases du système Ni-Re et Mo-Ni-Re (à 1200°C et à 1600°C) ont été proposées. En comparaison avec les études précédentes, le diagramme de phases Ni-Re déterminé au cours de ce travail a montré des différences significatives en termes de domaines d'homogénéité, des domaines de cristallisation et de température de réaction péritectique. La coupe isotherme à 1200°C du système Mo-Ni-Re proposée lors de cette étude a montré l'extension importante de la phase σ du système binaire Mo-Re et de la phase δ du système Mo-Ni dans le diagramme ternaire. En outre, la présence de deux phases ternaires jusque-là inconnues a également été observée. La coupe isotherme du système Mo-Ni-Re à 1600°C a également montré une grande extension de la phase σ dans le diagramme ternaire tandis que l'extension de la phase χ du système Mo-Re dans les deux coupes isothermes est limitée à un étroit domaine de composition. Les phases ternaires observées dans la coupe isotherme à 1200°C ne sont pas présentes dans la coupe isotherme à 1600°C. D'autre part, les études partielles des domaines de composition des phases dans les systèmes binaires Mo-Ni et Mo-Re ainsi que la détermination de la projection du liquidus du système Mo-Ni-Re ont également été effectuées. La projection du liquidus du système Mo-Ni-Re proposée lors de la présente étude a également montré des champs de cristallisation primaire de la phase σ de système Mo-Re et la solution solide de Re dans la région ternaire qui sont largement étendus. Puisque la coupe isotherme du système Mo-Ni-Re a montré un domaine d'homogénéité de la phase σ très étendu, la caractérisation structurale de la phase σ du système ternaire Mo-Ni-Re a été effectuée en mettant l'accent sur la détermination de l'occupation des sites en fonction de la composition par affinement de Rietveld combiné des données de diffraction des rayons X et des neutrons. Les résultats expérimentaux recueillis au cours de cette étude ainsi que les informations disponibles dans la littérature ont été utilisés comme données d'entrée pour la modélisation thermodynamique du système Mo-Ni-Re. La description thermodynamique du système Mo-Re a été prise de la littérature tandis que les optimisations thermodynamiques des systèmes Mo-Ni, Ni-Re et Mo-Ni-Re ont été effectuées au cours de ce travail avec la méthode CALHAD.Mots-clés: Mo-Ni, Mo-Re, Ni-Re, Mo-Ni-Re; diagramme de phases; coupe isotherme; caractérisation structurale; modélisation thermodynamique; méthode CALPHAD / The Mo-Ni-Re system is one of the important subsystems of the Ni based superalloys engineered for use in high temperature applications. Considering the contradictions among previously reported information, the present study was devoted to the complete experimental determination of the phase equilibria in the Mo-Ni-Re system, structural characterization of its intermetallic phases and thermodynamic modeling of the system with the help of the CALPHAD method. The experimental investigation of phase equilibria was carried out with the help of equilibrated alloys and phase diagrams of the Ni-Re and Mo-Ni-Re system (at 1200°C and 1600°C) were proposed. In comparison with previous investigations, the Ni-Re phase diagram determined during the present study showed significant difference in terms of homogeneity domains, freezing ranges and peritectic reaction temperature. The 1200°C isothermal section of the Mo-Ni-Re system proposed during the present study showed large extension of the Mo-Re σ phase and Mo-Ni δ phase in the ternary region. In addition, presence of two previously unknown ternary phases was also observed. The isothermal section of the Mo-Ni-Re system at 1600°C also showed large extension of σ phase in the ternary region whereas extension of the Mo-Re χ phase in both isothermal sections was restricted to narrow composition range. The presence of the ternary phases observed in the 1200°C isothermal was not evidenced in 1600°C isothermal section. On the other hand, partial investigations of phase boundaries in the Mo-Ni and Mo-Re binary systems and determination of liquidus projection of the Mo-Ni-Re system was also carried out. The liquidus projection of the Mo-Ni-Re system proposed during present study also showed largely extended primary crystallization fields of the Mo-Re σ phase and Re solid solution in the ternary region. Since isothermal sections of the Mo-Ni-Re system showed largely extended homogeneity domain of σ, structural characterization of the Mo-Ni-Re σ with particular emphasis on determination of site occupancy trends as a function of composition was carried out by combined Rietveld refinement of the X-ray and neutron diffraction data. The experimental results gathered during the present study along with the information available in the literature were used as input for thermodynamic modeling of the Mo-Ni-Re system. The thermodynamic description of the Mo-Re system was taken from literature whereas thermodynamic modeling of the Mo-Ni, Ni-Re and Mo-Ni-Re system was carried out during the present study with the help of the CALHAD method.Keywords: Mo-Ni; Mo-Re; Ni-Re; Mo-Ni-Re; phase diagram; isothermal section; structural characterization; thermodynamic modeling; CALPHAD method

Mo-Ni-Re

Diagramme de phases

Modélisation thermodynamique

Mo-Ni-Re

Phase diagram

Thermodynamic modeling

Modélisation hydrodynamique d'une torche à plasma couplée inductivement / Hydrodynamic modelling of inductively coupled plasma torch

Bendjebbar, Fatna

09 April 2013

L’objectif de cette thèse était la modélisation numérique de la torche à plasma à couplage inductive. (ICP). Nous avons établi les bases de données nécessaires : composition, propriétés thermodynamiques et de transport appliqués aux mélanges d’argon, d’acide nitrique et d’eau. Le modèle hydrodynamique de la torche ICP (7 spires) considère le plasma à l'équilibre thermodynamique et couple les équations de Navier-Stokes pour décrire l'écoulement du plasma aux équations de Maxwell pour décrire l'évolution du champ électrique et du champ magnétique. / The purpose of the work was the numerical modeling of the inductive coupling plasma torch. (ICP). We have established the necessary databases: composition, thermodynamic and transport properties applied to argon mixtures of nitric acid and water. The hydrodynamic model of the ICP torch (7 coils) considers the plasma at thermodynamic equilibrium and uses the Navier-Stokes equations to describe the plasma flow and the Maxwell equations to describe the evolution of the electric field and the magnetic field.

Plasma couplé inductivement

Modèle hydrodynamique

Inductively coupled plasma

Thermodynamic and transport properties

Hydrodynamic model

Symetrické aminofosfináty / Symmetrical aminophosphinates

Procházková, Soňa

January 2012

Title: Symmetrical aminophosphinates Author: Bc. Soňa Procházková Department of Inorganic Chemistry, Faculty of Science, Charles University Supervisor: RNDr. Vojtěch Kubíček, Ph.D. Supervisor's email address: kubicek@natur.cuni.cz ABSTRACT Two types of α-aminophosphinates were prepared and studied: phosphinate analogues of iminodiacetic acid − aminobis(methyl(hydroxymethyl)phosphinic acid) (IDPhm ) and aminobis(methyl(2-carboxyethyl)phosphinic acid) (IDPce ), and bis(aminomethyl- phosphinates) − (hydroxy(fenyl)methylen)bis(aminomethylphosphinic acid) (PheOHABPin) and (methylen)bis(aminomethylphosphinic acid) (ABPin). All prepared compounds were fully characterized (by NMR, MS, elemental analysis). One crystal structure was determined by X-ray singlecrystal analysis. The diphosphinates were synthesized by Mannich type reaction, whereas the bis(aminomethylphosphinates) were prepared by multistep synthesis including reactive silylesters. Compounds were prepared in moderate or good yields Acid-base and coordination properties of ligands were investigated and compared by potentiometric and NMR titrations. The values of protonation constants of aminogroups, which determine stability of complexes, showed surprising results. An extremely low basicity of nitrogen atom was found in diphosphinates. So, these compounds...