Spelling suggestions: "subject:"liquidphase"" "subject:"fluidphase""
81 |
Interactions et assemblages de prolamines du blé / Interactions and assemblies of wheat prolaminsPincemaille, Justine 22 November 2018 (has links)
Ce travail de thèse vise à apporter des connaissances structurales et fonctionnelles sur les protéines du gluten. Pour cela, nous utilisons les concepts et méthodes de la physique des polymères et de la matière molle. Plus précisément, nous optimisons un protocole d’extraction basé sur la séparation de phases liquide-liquide. Ce dernier permet d’obtenir des isolats de protéines à différents rapports massiques gluténines/gliadines que nous étudions ensuite dans un solvant eau/éthanol 50/50 (v/v). Les résultats, montrent que les protéines se comportent comme des chaînes de polymères en solvant θ, en régime dilué et semi-dilué avec des tailles caractéristiques définis par diffusion de rayons X et de neutrons aux petits angles. De plus, 2 tailles d’objets sont distinguées en régime dilué par diffusion dynamique de la lumière: d’une part des protéines monomériques de l’ordre d’une dizaine de nanomètres associées aux et -gliadines et à des polymères de gluténines de faibles masses molaires et d’autre part des assemblages polymériques de l’ordre de 100 nm, principalement composés de ω-gliadines et polymères de gluténines de haute masse molaire. Ces assemblages sont mis en avant par une combinaison de mesures réalisées par chromatographie d’exclusion de taille et par fractionnement par flux de forces asymétrique et permettent de rationaliser les diagrammes de phases de ces mélanges protéiques, en fonction de la température. L’étude de la dynamique de séparation de phases de ces mélanges protéiques, par diffusion de rayons X aux petits angles, montre que celle-ci est pilotée par un phénomène de décomposition spinodale. Cette décomposition peut être arrêtée lors de trempes en température profondes mais également observée à toutes les températures de trempe, pour les échantillons les plus riches en gluténines, formant un gel dès le régime monophasique, d’après leur étude par rhéologie / The aim of this thesis is to provide structural and functional knowledge on wheat gluten proteins. For that, we use the physical methods and the concept of soft matter. We optimize an extraction protocol based on a liquid-liquid phase separation. With this protocol, we obtain protein batches with different glutenin/gliadin mass ratios, which we then study in a 50/50 water/ethanol solvent (v/v). We show that proteins behave like polymer chains in θ solvent in dilute and semi-dilute regime, whose characteristic size are extracted by small angle X-ray and neutron scattering. Moreover, two sizes of objects are evidenced in dilute regime by dynamic light scattering: monomeric proteins with a size around 10 nm which can be associated to α/β, and γ-gliadins and polymeric glutenins with low molecular weight and polymeric assemblies with a size around 100 nm composed of ω-gliadins and glutenins polymers with high molecular weight. These assemblies are revealed by a combination of size exclusion chromatography and asymmetric flow field flow fractionation and allow one to rationalize the phase diagrams of the protein mixtures with temperature. The study of the dynamics of the phase separation of these protein mixtures by small angle X-ray scattering shows that the phase separation proceeds through a spinodal decomposition phenomenon. An arrested phase separation is observed for deep quenches but also at all temperature quenches for the most glutenin rich samples, which are gels in the monophasic regime, as confirmed by rheology.
|
82 |
Análise enantiosseletiva de venlafaxina e de seus principais metabólitos - aplicações em estudos de biotransformação in vitro e in vivo / Enantioselective analysis of venlafaxine and its major metabolites application to in vitro and in vivo biotransformation studiesFonseca, Patricia da 08 September 2011 (has links)
A microextração em fase líquida com membranas cilíndricas ocas (HF-LPME) é uma técnica bastante interessante de preparação de amostras, uma vez que com pequenas quantidades de solventes orgânicos é possível a extração dos analitos presentes em matrizes complexas. Sendo assim, essa técnica foi empregada para extração da venlafaxina (VEN) e seus metabólitos em fração microssomal de fígado de ratos e plasma, visando o desenvolvimento de métodos para análise enantiosseletiva desses analitos. Esses métodos foram então empregados em um estudo in vitro de biotransformação da VEN e em um estudo piloto de disposição cinética em ratos e humanos. A VEN é um fármaco quiral empregado no tratamento da depressão, cujas propriedades farmacocinéticas e farmacodinâmicas são estereosseletivas. Após a otimização das condições de extração por HF-LPME, foram obtidas recuperações de 12-60%. O método empregado no estudo in vitro de biotransformação da VEN foi desenvolvido usando a coluna ChiralpaK AD®, fase móvel composta por hexano : 2-propanol (95:5, v/v) + 0,025% de dietilamina (DEA) e detecção por absorção no UV. A coluna ChiralpaK AD-H® e a fase móvel composta por metanol : etanol (70:30, v/v) + 0,025% de DEA foram empregadas para análise da VEN e seus metabólitos em plasma. Para esse método, empregou-se a detecção por espectrometria de massas visando à obtenção de menores limites de quantificação. O método empregado para a determinação da VEN e de seus metabólitos em fração microssomal de fígado de ratos foi linear no intervalo de 200 a 5000 ng mL-1 e o método empregado para a determinação da VEN e de seus metabólitos em amostras de plasma foi linear no intervalo de 5 a 500 ng mL-1. Os métodos analíticos desenvolvidos para determinação da VEN e seus metabólitos nas matrizes biológicas foram aplicados em estudos de biotransformação in vitro e em estudos de disposição cinética em duas espécies (ratos e humanos). O objetivo destes estudos foi avaliar a correlação da biotransformação entre as diferentes espécies avaliadas e comparar os resultados obtidos nos estudos in vitro com os verificados nos estudos in vivo. Os resultados dos estudos empregando fração microssomal de fígado de ratos são semelhantes aos obtidos no estudo de disposição cinética em ratos, com formação mais pronunciada da Ndesmetilvenlafaxina (N-VEN) e com produção prioritária do enantiômero (-)-(R). Comparando-se os estudos de disposição cinética em ratos e humanos, observa-se enantiosseletividade na biotransformação da VEN com a (-)-(R)-VEN sendo preferencialmente biotransformada. Entretanto, em humanos observa-se que a (-)- (R)-O-desmetilvenlafaxina ((-)-(R)-O-VEN) é formada em maior proporção enquanto que, em ratos, a (-)-(R)-N-VEN é preferencialmente formada. / Hollow Fiber-Liquid Phase Microextraction (HF-LPME) is a very interesting technique for sample preparation, since it uses small amounts of organic solvents to extract drugs present in complex matrices. Thus, this technique was employed for the extraction of venlafaxine (VEN) and its metabolites from rat liver microsomal fraction and plasma, aiming the development of methods for the enantioselective analysis of these analytes. These methods were then applied to study the in vitro biotransformation and the kinetic disposition of VEN in rats and humans. VEN is a chiral drug used in the treatment of depression, whose pharmacokinetic and pharmacodynamic properties are stereoselective. After the optimization of the HFLPME conditions, recoveries of 12-60% were obtained. The method employed in the in vitro biotransformation study of VEN was developed using a ChiralpaK AD® column, mobile phase consisting of hexane : 2-propanol (95:5, v/v) + 0.025% of diethylamine (DEA) and UV detection. The ChiralpaK AD-H® column and the mobile phase consisting of methanol : ethanol (70:30, v/v) + 0.025% of DEA were employed for the analysis of VEN and its metabolites in plasma. In order to obtain lower quantification limits, mass spectrometry detection was used in this method. The method used for the determination of VEN and its metabolites in rat liver microsomal fraction was linear over the concentration range of 200 to 5000 ng mL-1 whereas the method used for the determination of VEN and its metabolites in plasma was linear in the range of 5 to 500 ng mL-1. The developed methods for the determination of VEN in biological matrices were applied to an in vitro biotransformation study and to kinetic disposition studies in two species (rats and humans). The objective of these studies was to evaluate the correlation of the biotransformation between different species and to compare the results of the in vitro and in vivo studies. The results obtained using rat liver microsomal fraction were similar to those obtained in the rat kinetic disposition study, with more pronounced formation of N-desmethylvenlafaxine (NVEN) and major production of the (-)-(R) enantiomer. Comparing the kinetic disposition studies in rats and humans, the enantioselectivity in the biotransformation of VEN with (-)-(R)-VEN being preferentially biotransformed was observed for both species. However, (-)-(R)-O-desmethylvenlafaxine ((-)-(R)-O-VEN) is preferentially formed in humans whereas the major metabolite in rat plasma is (-)-(R)-N-VEN.
|
83 |
Supramolecular approaches to graphene : generation of functional hybrid assemblies / L'approche supramoléculaire appliquée au graphène : production d'assemblées hybrides fonctionnaliséesHaar, Sébastien 30 September 2015 (has links)
Cette thèse démontre le potentiel dont dispose l’exfoliation en phase liquide du graphite dans le but d’obtenir des feuillets de graphène dispersés dans un solvant organique. Ainsi le mécanisme d’exfoliation a été étudié en profondeur, en particulier, l’influence de plusieurs paramètres (température, puissance et solvants). Le choix de ses paramètres se montre crucial dans le contrôle du procédé, et pour l’obtention des feuillets de graphène ayant une taille ciblée. Il est donc possible de fabriquer des nano-feuillets de quelques dizaines de nanomètre qui en plus possèdent des propriétés de photoluminescence.Dans le but de comprendre le mécanisme d’exfoliation en phase liquide assistée par des molécules, une nouvelle approche a été mise au point : l’approche supramoléculaire. Cette approche se base sur l’utilisation de surfactants d’un nouveau type. En effet, les molécules sélectionnées possèdent une longue chaine alkyle. Cette chaine s’adsorbe sur la surface du graphène et permet de stabiliser les feuillets lors de l’exfoliation. L’influence de la taille de la chaine alkyle de ces molécules lors de l’exfoliation a été vérifiée. De plus, ces molécules ont été équipées de différentes fonctions supramoléculaires afin qu’elles puissent former des dimères sur la surface du graphène. L’ajout de ces molécules augmente non seulement le rendement d’exfoliation mais aussi le nombre de mono-feuillets présents dans ces dispersions. Ces dispersions présentent des propriétés conductrices lorsqu’elles sont déposées sur des substrats. Une nouvelles méthode de déposition a été mise au point afin d’améliorer et d’augmenter la conductivité mais aussi le pourcentage de transparence. / This thesis demonstrates the potential of exfoliation of the graphite in the liquid phase in order to obtain graphene sheets dispersed in an organic solvent. Thus the exfoliation mechanism has been studied, in particular, the influence of several parameters (temperature, power and solvents). The choice of parameters is actually crucial for the control of the process, and to obtain graphene sheets having a targeted size. It is therefore possible to manufacture nanosheets of several tens of nanometers, which in addition exhibit photoluminescence properties.In order to understand the exfoliation mechanism in liquid phase assisted by molecules, a new approach has been developed: the supramolecular approach. This approach is based on using a new type of surfactant. Indeed, the selected molecules carry a long alkyl chain. This chain is adsorbed on the surface of graphene and can stabilize the sheets during exfoliation. The influence of the size of the alkyl chain of these molecules during exfoliation was verified. Furthermore, these molecules have been equipped with various supramolecular functions, which can form dimers on the surface of graphene. The addition of these molecules not only increases exfoliation performance but also the number of mono-layers present in these dispersions. These dispersions have conductive properties when deposited on substrates. A new deposition method was developed to enhance and increase conductivity but also the percentage of transparency.
|
84 |
Neue Ansätze zur Monomersequenzkontrolle in synthetischen Polymeren / New approaches for monomer sequence control in synthetic polymersPfeifer, Sebastian January 2011 (has links)
Von der Natur geschaffene Polymere faszinieren Polymerforscher durch ihre spezielle auf eine bestimmte Aufgabe ausgerichtete Funktionalität. Diese ergibt sich aus ihrer Bausteinabfolge uber die Ausbildung von Uberstrukturen. Dazu zählen zum Beispiel Proteine (Eiweiße), aus deren Gestalt sich wichtige Eigenschaften ergeben. Diese Struktureigenschaftsbeziehung gilt ebenso für funktionelle synthetische Makromoleküle. Demzufolge kann die Kontrolle der Monomersequenz in Polymeren bedeutend für die resultierende Form des Polymermoleküls sein.
Obwohl die Synthese von synthetischen Polymeren mit der Komplexität und der Größe von Proteinen in absehbarer Zeit wahrscheinlich nicht gelingen wird, können wir von der Natur lernen, um neuartige Polymermaterialien mit definierten Strukturen (Sequenzen) zu synthetisieren. Deshalb ist die Entwicklung neuer und besserer Techniken zur Strukturkontrolle von großem Interesse für die Synthese von Makromolekülen, die perfekt auf ihre Funktion zugeschnitten sind.
Im Gegensatz zu der Anzahl fortgeschrittener Synthesestrategien zum Design aus- gefallener Polymerarchitekturen – wie zum Beispiel Sterne oder baumartige Polymere (Dendrimere) – gibt es vergleichsweise wenig Ansätze zur echten Sequenzkontrolle in synthetischen Polymeren. Diese Arbeit stellt zwei unterschiedliche Techniken vor, mit denen die Monomersequenz innerhalb eines Polymers kontrolliert werden kann.
Gerade bei den großtechnisch bedeutsamen radikalischen Polymerisationen ist die Sequenzkontrolle schwierig, weil die chemischen Bausteine (Monomere) sehr reaktiv sind. Im ersten Teil dieser Arbeit werden die Eigenschaften zweier Monomere (Styrol und N-substituiertes Maleinimid) geschickt ausgenutzt, um in eine Styrolkette definierte und lokal scharf abgegrenzte Funktionssequenzen einzubauen. Uber eine kontrollierte radikalische Polymerisationsmethode (ATRP) wurden in einer Ein-Topf-Synthese über das N-substituierte Maleinimid chemische Funktionen an einer beliebigen Stelle der Polystyrolkette eingebaut. Es gelang ebenfalls, vier unterschiedliche Funktionen in einer vorgegebenen Sequenz in die Polymerkette einzubauen. Diese Technik wurde an zwanzig verschiedenen N-substituierten Maleinimiden getestet, die meisten konnten erfolgreich in die Polymerkette integriert werden.
In dem zweiten in dieser Arbeit vorgestellten Ansatz zur Sequenzkontrolle, wurde der schrittweise Aufbau eines Oligomers aus hydrophoben und hydrophilen Segmenten (ω-Alkin-Carbonsäure bzw. α-Amin-ω-Azid-Oligoethylenglycol) an einem löslichen Polymerträger durchgeführt. Das Oligomer konnte durch die geschickte Auswahl der Verknüpfungsreaktionen ohne Schutzgruppenstrategie synthetisiert werden. Der lösliche Polymerträger aus Polystyrol wurde mittels ATRP selbst synthetisiert. Dazu wurde ein Startreagenz (Initiator) entwickelt, das in der Mitte einen säurelabilen Linker, auf der einen Seite die initiierende Einheit und auf der anderen die Ankergruppe für die Anbindung des ersten Segments trägt. Der lösliche Polymerträger ermöglichte einerseits die schrittweise Synthese in Lösung. Andererseits konnten überschüssige Reagenzien und Nebenprodukte zwischen den Reaktionsschritten durch Fällung in einem Nicht-Lösungsmittel einfach abgetrennt werden. Der Linker ermöglichte die Abtrennung des Oligomers aus jeweils drei hydrophoben und hydrophilen Einheiten nach der Synthese. / Polymer scientists are impressed by polymers created by nature. This is caused by their structure which is aimed to fulfill very special functions. The structure is primary built by sequential covalent linking of building units. Secondly, supramolecular aggregation leads to three-dimensional alignment. The sequence of the building blocks has a high influence on the higher molecular arrangement. Proteins are only one example for supramolecular structures which have special functions because of their supramolecular arrangement. This structure-property relationship is also possible for synthetic polymers. For this reason the control of monomer sequences in synthtic polymers is just as important for the resulting structure of a synthetic polymer molecule.
Even though the synthesis of polymers with complex strucures and sizes as in nature is impossible in near future. But the development of new and better techniques for sequence control in synthetic polymers is of high importance to create well defined macromolecular structures which are tailor-made for their function.
In contrast to a lot of advanced synthethis strategies for the design of complex polymer architechtures (e.g. brushes, stars, or dendrimers) their are less approaches for a monomer sequence control in synthetic polymers. This work presents two different techniques for controlling the monomer sequence inside a polymer.
Especially in technologically significant radical polymerization it is difficult to control the monomer sequence because radical species are very reactive and the addition of a monomer to the radical function is not selective. The first approach makes use of the properties of two monomers (styrene and N-substituted maleimides) to add chemical funtions locally inside a polystyrene chain. By addition of N-functionalized maleimides during the polymerization of styrene chemical functions could be added at any desired position inside the polystyrene chain. This technique was tested on 20 different N-substituted maleimides. Most of them were incorporated successfully into the polymer chain.
The second monomer sequence control approach is a stepwise synthesis of an oligomer made of short alternating hydrophobic and hydrophilic segments on a soluble polymer support. Two building blocks were used: ω-alkyne carboxylic acid (A-B) and α-amine-ω-azide oligoethylene glycol (C-D). The linking of the segments was done by applying two very efficient chemical reactions, namely 1,3-dipolar cycloaddition of terminal alkynes (A) and azides (D) and amidification of carboxylic acids (B) with primary amines (C). These two reactions proceed chemoselectively in an ABCD multifunctional mixture without a protection chemistry strategy.
The polystyrene support was synthesized by atom transfer radical polymerization (ATRP) in the presence of an azido-functionalized ATRP initiator containing a labile p-alkoxybenzyl ester linker. Depending on the choise of solvent, the soluble polymer support was used in solution during the coupling reactions or was precipitated for an easy removal of excessive reagents and by-products. The acid-labile linker could be cleaved by trifluoroacetic acid treatment to obtain a hydrophilic/hydrophobic block copolymer.
|
85 |
Process Kinetics of Transient Liquid PhaseTurriff, Dennis Michael Ryan 09 1900 (has links)
The problem of inadequate measurement techniques for quantifying the isothermal solidification process during transient liquid phase sintering (TLPS) in binary isomorphous systems such as Ni-Cu, and the resulting uncertainty regarding the solidification mechanism and its sensitivity to important process parameters, has been investigated. A unique combination of differential scanning calorimetry (DSC), neutron diffraction (ND), and metallographic techniques has enabled the quantitative characterization of important TLPS stages (i.e., solid-state sintering, melting and dissolution, isothermal solidification, and homogenization) as well as verifying the re-melt behaviour of post-sintered specimens and measuring variable melting point (VMP) properties. This has resulted in the advancement of the fundamental understanding of liquid formation and its removal mechanism during isothermal, or diffusional, solidification. The Ni-Cu system was chosen for experimentation due to its commercial relevance as a braze filler material and also because it is an ideal model system (due to its isomorphous character) that is not well understood on a quantitative or phenomenological basis. Samples consisted of elemental Ni and Cu powder mixtures of varying particle size and composition.
In DSC experiments, the progress of isothermal solidification was determined by measuring the enthalpy of melting and solidification after isothermal hold periods of varying length and comparing these to the measured enthalpy of pure Cu. The low melting enthalpies measured for all Ni/Cu mixtures heated just past the Cu melting point (1090°C) indicate that solid-state sintering and interdiffusion during heat-up significantly suppress initial liquid formation and densification from the wetting liquid. For samples heated well past the Cu melting point (1140°C), Ni dissolution causes increased initial liquid fractions and densification. It was found that significantly more time was required for complete liquid removal at 1140°C vs. 1090°C. This is attributed to the observed increase in initial liquid fractions formed at higher processing temperatures due to the dissolution of Ni. This effectively counteracts the increased diffusivities at these temperatures, and thus more time is required to completely remove the increased liquid content. TLP mixtures sintered at 1140°C using three different particle sizes revealed that fine base metal Ni particles cause high degrees of solid-state interdiffusion during heat-up, small initial liquid fractions, and accelerated liquid removal rates due to high surface area/volume ratios. A diffusion-based analytical model was developed to account for these effects (i.e., particle size, temperature, solid-state sintering, and dissolution). Comparison with experimental DSC results reveals that this model can accurately predict liquid removal given accurate diffusivities. Metallographic analysis of post-sintered DSC specimens via SEM and EDS indicates that isothermal liquid solidification leaves behind Ni-rich cores surrounded by Cu-rich matrix regions having compositions given by the Ni-Cu phase diagram solidus (CS) at a selected isothermal processing temperature (TP).
ND experiments were used to investigate the melting event and interdiffusion during the isothermal hold segment by analyzing the evolution of the {200} FCC peaks of Ni and Cu. ND patterns were collected in situ at 1 minute intervals during prolonged sintering cycles for larger powder specimens. The Cu melting event was characterized by an abrupt decrease in Cu peak intensity at 1085°C as well as a shift towards higher 2 angles corresponding to lower Cu contents. This shifted residual peak (hereafter referred to as the CS peak) originates from regions of the specimen having compositions near solidus at TP. Immediately following the melting event, the evolution of ND patterns shows that these CS peaks grow rapidly, indicating the isothermal growth of a Cu-rich phase. These in situ findings confirmed the metallographic and DSC data and indicated that isothermal solidification of the liquid phase proceeds via the growth of a solute-rich solid solution layer surrounding the Ni particles. This occurs by the transient progression of the solid/liquid interface at compositions given by the liquidus and solidus (CS/CL). During sintering, diffraction intensities gradually increased at intermediate 2 angles between previous Ni and Cu peaks. ND patterns gradually evolved from initially having a broad double-peak profile to a sharper single-peak profile due to increased Ni-Cu interdiffusion. The 2position and width of the post-sintered peaks indicated very homogeneous sintered alloys. Metallographic analysis of post-sintered specimens having undergone prolonged sintering and homogenization revealed extensive Kirkendall pore formation from unequal diffusivities (DCu > DNi).
In this study, the unique combination of diffusion-based modelling as well as DSC, ND, and supporting metallographic analysis has enabled the identification of characteristic sintering behaviour, important process parameters, and processing windows for TLPS in Ni-Cu systems. Quantitative and in situ information of this nature is absent in the previous TLPS literature.
|
86 |
Coated Carbon Nanotubes and Carbon Fibers: Synthesis and ApplicationsJanuary 2011 (has links)
Carbon nanotubes have been of great interest given their unique electronic and mechanical properties. Scholars have focused on the addition of carbon nanotubes to various matrices in order to develop novel materials. These new hybrid materials would combine the properties of both the nanotubes and the matrix of choice, which can both enhance the mechanical and electronic properties of the matrix material, and allow for the matrix to be used for other applications. In order to take advantage of the properties of the nanotubes, it is vital for them to be well dispersed in a solution or matrix as individual tubes, rather than as bundles. Additionally, it is cost effective to have individually dispersed tubes in a matrix. In order to individually disperse the tubes in the matrix, they can be pre-treated or functionalized via both covalent and non covalent processes. Subsequent to functionalization, the nanotubes can be coated with the matrix material or other metal compounds. This can help with the dispersion and interface interaction with the matrix material, or create materials with novel properties. This thesis focuses on conditions of growing various metal compounds or metal oxides on nanotubes using chemical bath deposition (CBD) and liquid phase deposition (LPD) methods. CBD and LPD use aqueous mediums for growth and deposition of compounds, which makes it both environmentally friendly and cost effective. Different pre-treatments are first employed on the nanotubes in order for them to be both well dispersed in solution and provide nucleation sites for the deposition and growth of various metal and metal oxides on the surface of the nanotubes. Once an ideal deposition is achieved, applications of the coated tubes are studied, tested and discussed.
|
87 |
Process Kinetics of Transient Liquid PhaseTurriff, Dennis Michael Ryan 09 1900 (has links)
The problem of inadequate measurement techniques for quantifying the isothermal solidification process during transient liquid phase sintering (TLPS) in binary isomorphous systems such as Ni-Cu, and the resulting uncertainty regarding the solidification mechanism and its sensitivity to important process parameters, has been investigated. A unique combination of differential scanning calorimetry (DSC), neutron diffraction (ND), and metallographic techniques has enabled the quantitative characterization of important TLPS stages (i.e., solid-state sintering, melting and dissolution, isothermal solidification, and homogenization) as well as verifying the re-melt behaviour of post-sintered specimens and measuring variable melting point (VMP) properties. This has resulted in the advancement of the fundamental understanding of liquid formation and its removal mechanism during isothermal, or diffusional, solidification. The Ni-Cu system was chosen for experimentation due to its commercial relevance as a braze filler material and also because it is an ideal model system (due to its isomorphous character) that is not well understood on a quantitative or phenomenological basis. Samples consisted of elemental Ni and Cu powder mixtures of varying particle size and composition.
In DSC experiments, the progress of isothermal solidification was determined by measuring the enthalpy of melting and solidification after isothermal hold periods of varying length and comparing these to the measured enthalpy of pure Cu. The low melting enthalpies measured for all Ni/Cu mixtures heated just past the Cu melting point (1090°C) indicate that solid-state sintering and interdiffusion during heat-up significantly suppress initial liquid formation and densification from the wetting liquid. For samples heated well past the Cu melting point (1140°C), Ni dissolution causes increased initial liquid fractions and densification. It was found that significantly more time was required for complete liquid removal at 1140°C vs. 1090°C. This is attributed to the observed increase in initial liquid fractions formed at higher processing temperatures due to the dissolution of Ni. This effectively counteracts the increased diffusivities at these temperatures, and thus more time is required to completely remove the increased liquid content. TLP mixtures sintered at 1140°C using three different particle sizes revealed that fine base metal Ni particles cause high degrees of solid-state interdiffusion during heat-up, small initial liquid fractions, and accelerated liquid removal rates due to high surface area/volume ratios. A diffusion-based analytical model was developed to account for these effects (i.e., particle size, temperature, solid-state sintering, and dissolution). Comparison with experimental DSC results reveals that this model can accurately predict liquid removal given accurate diffusivities. Metallographic analysis of post-sintered DSC specimens via SEM and EDS indicates that isothermal liquid solidification leaves behind Ni-rich cores surrounded by Cu-rich matrix regions having compositions given by the Ni-Cu phase diagram solidus (CS) at a selected isothermal processing temperature (TP).
ND experiments were used to investigate the melting event and interdiffusion during the isothermal hold segment by analyzing the evolution of the {200} FCC peaks of Ni and Cu. ND patterns were collected in situ at 1 minute intervals during prolonged sintering cycles for larger powder specimens. The Cu melting event was characterized by an abrupt decrease in Cu peak intensity at 1085°C as well as a shift towards higher 2 angles corresponding to lower Cu contents. This shifted residual peak (hereafter referred to as the CS peak) originates from regions of the specimen having compositions near solidus at TP. Immediately following the melting event, the evolution of ND patterns shows that these CS peaks grow rapidly, indicating the isothermal growth of a Cu-rich phase. These in situ findings confirmed the metallographic and DSC data and indicated that isothermal solidification of the liquid phase proceeds via the growth of a solute-rich solid solution layer surrounding the Ni particles. This occurs by the transient progression of the solid/liquid interface at compositions given by the liquidus and solidus (CS/CL). During sintering, diffraction intensities gradually increased at intermediate 2 angles between previous Ni and Cu peaks. ND patterns gradually evolved from initially having a broad double-peak profile to a sharper single-peak profile due to increased Ni-Cu interdiffusion. The 2position and width of the post-sintered peaks indicated very homogeneous sintered alloys. Metallographic analysis of post-sintered specimens having undergone prolonged sintering and homogenization revealed extensive Kirkendall pore formation from unequal diffusivities (DCu > DNi).
In this study, the unique combination of diffusion-based modelling as well as DSC, ND, and supporting metallographic analysis has enabled the identification of characteristic sintering behaviour, important process parameters, and processing windows for TLPS in Ni-Cu systems. Quantitative and in situ information of this nature is absent in the previous TLPS literature.
|
88 |
Quantum Cascade Lasers for Mid-Infrared Chemical SensingCharlton, Christy 23 November 2005 (has links)
The mid-infrared (MIR) spectral range (2-20 m) is particularly useful for chemical sensing due to the excitation of fundamental rotational and vibrational modes. In the fingerprint region (10-20 m), most organic analytes have unique absorption patterns; absorption measurements in this region provide molecule-specific information with high sensitivity.
Quantum cascade lasers (QCLs) present an ideal light source for (MIR) chemical sensing due to their narrow linewidth, high spectral density, compact size, and ease of fabrication of nearly any MIR wavelength. As the emission wavelength is dependent on layer size within the heterostructure rather than material composition, various wavelengths in the MIR can be achieved through bandstructure engineering.
High sensitivity measurements have been achieved in both gas and liquid phase by developing integrated sensing systems. The laser emission frequency is selected to match a strong absorption feature for the analyte of interest where no other interfering bands are located. A waveguide is then developed to fit the application and wavelength used.
Gas sensing applications incorporate silica hollow waveguides (HWG) and an OmniGuide fiber (or photonic bandgap HWG). Analyte gas is injected into the hollow core allowing the HWG or OmniGuide to serve simultaneously as a waveguide and miniaturized gas cell. Sensitivities of parts per billion are achieved with a response time of 8 s and a sample volume of approximately 1 mL.
Liquid sensing is achieved via evanescent wave measurements with planar waveguides of silver halide (AgX) and gallium arsenide (GaAs). GaAs waveguides developed in this work have a thickness on the order of the wavelength of light achieving single-mode waveguides, providing a significant improvement in evanescent field strength over conventional multimode fibers. Liquid samples of L volume at the waveguide surfaces are detected.
QCLs have begun to be utilized as a light source in the MIR regime over the last decade. The next step in this field is the development of compact and highly integrated device platforms which take full advantage of this technology. The sensing demonstrations in this work advance the field towards finding key applications in medical, biological, environmental, and atmospheric measurements.
|
89 |
Study of cation-dominated ionic-electronic materials and devicesGreenlee, Jordan Douglas 08 June 2015 (has links)
The memristor is a two-terminal semiconductor device that is able to mimic the conductance response of synapses and can be utilized in next-generation computing platforms that will compute similarly to the mammalian brain. The initial memristor implementation is operated by the digital formation and dissolution of a highly conductive filament. However, an analog memristor is necessary to mimic analog synapses in the mammalian brain. To understand the mechanisms of operation and impact of different device designs, analog memristors were fabricated, modeled, and characterized. To realize analog memristors, lithiated transition metal oxides were grown by molecular beam epitaxy, RF sputtering, and liquid phase electro-epitaxy. Analog memristors were modeled using a finite element model simulation and characterized with X-ray absorption spectroscopy, impedance spectroscopy, and other electrical methods. It was shown that lithium movement facilitates analog memristance and nanoscopic ionic-electronic memristors with ion-soluble electrodes can be key enabling devices for brain-inspired computing.
|
90 |
Numerical Simulation and Experimental Study of Transient Liquid Phase Bonding of Single Crystal SuperalloysGhoneim, Adam 07 October 2011 (has links)
The primary goals of the research in this dissertation are to perform a systematic study to identify and understand the fundamental cause of prolonged processing time during transient liquid phase bonding of difficult-to-bond single crystal Ni-base materials, and use the acquired knowledge to develop an effective way to reduce the isothermal solidification time without sacrificing the single crystalline nature of the base materials. To achieve these objectives, a multi-scale numerical modeling approach, that involves the use of a 2-D fully implicit moving-mesh Finite Element method and a Cellular Automata method, was developed to theoretically investigate the cause of long isothermal solidification times and determine a viable way to minimize the problem. Subsequently, the predictions of the theoretical models are experimentally validated.
Contrary to previous suggestions, numerical calculations and experimental verifications have shown that enhanced intergranular diffusivity has a negligible effect on solidification time in cast superalloys and that another important factor must be responsible. In addition, it was found that the concept of competition between solute diffusivity and solubility as predicted by standard analytical TLP bonding models and reported in the literature as a possible cause of long solidification times is not suitable to explain salient experimental observations. In contrast, however, this study shows that the problem of long solidification times, which anomalously increase with temperature is fundamentally caused by departure from diffusion controlled parabolic migration of the liquid-solid interface with holding time during bonding due to a significant reduction in the solute concentration gradient in the base material.
Theoretical analyses showed it is possible to minimize the solidification time and prevent formation of stray-grains in joints between single crystal substrates by using a composite powder mixture of brazing alloy and base alloy as the interlayer material, which prior to the present work has been reported to be unsuitable. This was experimentally verified and the use of the composite powder mixture as interlayer material to reduce the solidification time and avoid stray-grain formation during TLP bonding of single crystal superalloys has been reported for the first time in this research.
|
Page generated in 0.061 seconds