Etude de l'influence des paramètres nano et microstructuraux sur les propriétés thermoélectriques des siliciures de magnésium Mg2 (Si, Sn) de type -n / Influence of nano and microstructural parameters on the thermoelectric properties of n-type magnesium silicides Mg2(Si,Sn)

Bellanger, Philippe

28 April 2014

Ce travail de thèse porte sur l’étude de l’influence des paramètres nano et microstructuraux pour l’optimisation des propriétés thermoélectriques des siliciures de magnésium Mg2(Si,Sn) de type -n. Ces matériaux thermoélectriques ont été choisis pour leurs compatibilités avec une utilisation en génération de puissance dans le domaine de l’automobile.Par une approche combinatoire utilisant les couples de diffusion, il est premièrement ré investigué le diagramme de phase pseudo-binaire Mg2Si-Mg2Sn dans le but d’interpréter les microstructures observées. Il est ensuite présenté les effets expérimentaux des paramètres de densification par frittage flash (SPS) sur les microstructures et les propriétés thermoélectriques résultantes. Finalement, il est explicité à l’aide de la modélisation l’influence des paramètres microstructuraux sur les propriétés thermoélectriques de l’alliage optimisé et nanostructuré Mg2Si0,3875Sn0,6Sb0,0125. / This study presents the influence of nano and microstructural parameters to optimize thermoelectric properties of n-type magnesium silicides Mg2(Si,Sn). These thermoelectric materials are chosen for their compatibilities with power generation in automotive.From a combinatorial approach using diffusion couples, it is first reinvestigated the pseudo-binary phase diagram Mg2Si-Mg2Sn to rationalize the observed microstructures. Then the experimental effects of sintering parameters (SPS) on resulting microstructures and thermoelectric properties are presented. Finally, the influence of microstructural parameters on the thermoelectric properties of optimized and nanostructured Mg2Si0,3875Sn0,6Sb0,0125 alloys are explained through modelling.

Thermoélectricité

Couples de diffusion

Spark Plasma Sintering

Siliciures de magnésium

Diagramme de phase

Equation de Boltzmann

Approche combinatoire

Nanostructures

Thermoréflectivité

Thermoelectricity

Diffusion couples

Spark Plasma Sintering

Magnesium silicides

Phase diagram

Boltzmann equations

Combinatorial approach

Nanostructures

Thermoreflectivity

60.112 96

Desenvolvimento de nanocompósitos de alumina-carbeto de nióbio por sinterização não-convencional / Desarrollo de nanocomposites de alúmina-carburo de niobio obtenidos por sinterización no-convencional

Laís Ribeiro Rodrigues Alecrim

25 July 2017

Nanocompósitos de matriz de alumina (Al2O3) reforçada com uma segunda fase nanométrica apresentam melhores propriedades mecânicas, especialmente dureza, tenacidade à fratura e resistência ao desgaste, quando comparado à matriz monolítica. O carbeto de nióbio (NbC) possui propriedades que o tornam um material de reforço ideal em cerâmicas de matriz Al2O3, como alto ponto de fusão e dureza, baixa reatividade química e coeficiente de expansão térmica similar à Al2O3, prevenindo o aparecimento de trincas que diminuem a resistência do material. As maiores reservas de nióbio estão localizadas no Brasil e o estudo em torno do seu aproveitamento é importante para o país. Assim, o objetivo deste trabalho foi obter e caracterizar nanocompósitos de matriz de Al2O3 contendo 5% em volume de inclusões nanométricas de NbC obtidos por moagem reativa de alta energia, usando sinterização convencional, Spark Plasma Sintering (SPS) e micro-ondas. Para isso, os pós nanométricos precursores de Al2O3-NbC foram obtidos por moagem reativa de alta energia, realizada por 330 minutos em moinho tipo SPEX, desaglomerados, lixiviados com ácido clorídrico, adicionados à matriz de Al2O3 na proporção de 5% em volume e secos sob fluxo de ar. Os pós de Al2O3-5%vol.NbC foram sinterizados por diferentes métodos: convencional em atmosfera de argônio, micro-ondas e SPS, usando diferentes temperaturas. Os pós precursores foram caracterizados por difração de raios X (DRX), microscopia eletrônica de varredura (MEV) e medida de tamanho de partículas. Os nanocompósitos sinterizados convencionalmente e por SPS foram caracterizados quanto a sua microestrutura, densidade aparente em relação a densidade teórica e dureza por nanoindentação. Os nanocompósitos sinterizados por SPS foram caracterizados quanto ao módulo de Young por nanoindentação, tenacidade à fratura e resistência a flexão em três pontos. Os nanocompósitos sinterizados convencionalmente e por SPS foram caracterizados quanto à resistência ao desgaste por ensaios esfera no disco, usando esferas de WC-6%Co com cargas de 30 e 60 N e esferas de Al2O3 com cargas de 15 e 30 N. Os resultados mostram que a moagem reativa de alta energia foi completa e efetiva na obtenção de pós nanométricos, com tamanhos de cristalito iguais a 9,1 e 9,7 nm, para Al2O3 e NbC, respectivamente. Além disso, a desaglomeração, após o processo de moagem reativa de alta energia, foi eficaz na dispersão das inclusões de NbC na matriz de Al2O3. No entanto, não foi possível obter nanocompósitos de Al2O3-5%vol.NbC com alta densidade usando os processos de sinterização convencional (92-93 %DT) e micro-ondas (80-90 %DT). No processo de sinterização por SPS, os nanocompósitos apresentaram densidades próximas à teórica (99 %DT) e, consequentemente, melhores durezas e resistência ao desgaste, quando comparadas aos materiais obtidos em forno convencional. Os resultados obtidos na caracterização da resistência ao desgaste confirmaram que esta propriedade é influenciada por diversos fatores, como método e temperatura de sinterização, as esferas utilizadas como contra-materiais e cargas aplicadas durante o ensaio. Os resultados indicaram que nanocompósitos de Al2O3-5%vol.NbC sinterizados por SPS apresentam potencial para aplicações em diversos segmentos industriais, onde se exige materiais de alto desempenho mecânico e de desgaste. / Los nanocomposites de matriz alúmina (Al2O3) reforzados con una segunda fase nanométrica presentan mejores propiedades mecánicas, especialmente de dureza, tenacidad a la fractura y resistencia al desgaste, en comparación con el material monolítico de alúmina. Por otra parte, el carburo de niobio (NbC), como refuerzo de segunda fase, presenta propiedades que lo convierten en un material ideal para las cerámicas de matriz Al2O3, tales como alta temperatura de fusión, alta dureza, baja reactividad química y un coeficiente de expansión térmica similar al material de Al2O3, evitando así la aparición de grietas que disminuyen la resistencia del material. Actualmente, las mayores reservas de niobio se encuentran en Brasil y el estudio sobre su uso es un hito muy importante para el país. Por lo tanto, el objetivo de esta tesis es obtener y caracterizar nanocomposites de matriz de Al2O3 con una segunda fase del 5% en volumen de nanopartículas de NbC obtenidos por molienda reactiva de alta energía y, mediante la sinterización convencional, Spark Plasma Sintering (SPS) y microondas. Para ello, los polvos precursores nanométricos de Al2O3-NbC fueron obtenidos mediante molienda reactiva de alta energía, durante 330 minutos en molino SPEX, desaglomerados, lixiviados con ácido clorhídrico, añadidos a la matriz de Al2O3 en la proporción de 5% en volumen y secado bajo flujo de aire. Los polvos de Al2O3-5vol.%NbC fueron sinterizados por diferentes métodos: convencional bajo una atmósfera de argón, microondas y SPS usando diferentes temperaturas. Los polvos precursores se caracterizaron por difracción de rayos X (XRD), microscopía electrónica de barrido (SEM) y la medición del tamaño de partícula. Los nanocomposites sinterizados convencionalmente y mediante SPS se caracterizaron microestructuralmente, se estudió la densidad aparente y la dureza por nanoindentación. Los nanocomposites sinterizados mediante SPS fueron caracterizados mediante el módulo de Young por nanoindentación, la tenacidad a la fractura y la resistencia a la flexión en tres puntos. Por otra parte, los nanocomposites sinterizados convencionalmente y mediante SPS fueron caracterizados respecto a resistencia al desgaste mediante la técnica de \"ball-on-disc\", utilizando esferas de WC-6%Co con cargas 30 y 60 N y esferas de Al2O3 con cargas 15 y 30 N. Los resultados muestran que la molienda reactiva de alta energía ha sido completa y eficaz en la obtención de polvos nanométricos con tamaños de cristalito de 9,1 y 9,7 nm para la Al2O3 y NbC, respectivamente. Además, la desaglomeración, después del proceso de molienda reactiva de alta energía, fue eficaz en la dispersión de las inclusiones de NbC en la matriz de Al2O3. Sin embargo, no ha sido posible obtener nanocomposites de Al2O3-5vol.%NbC con alta densidad usando procesos de sinterización convencional (92-93 %DT) y microondas (80-90 %DT). En el proceso de sinterización mediante SPS, los nanocomposites presentaron densidades cercanas a la teórica (99 %DT) y, en con-secuencia, mejor dureza y resistencia al desgaste en comparación con los materiales obtenidos en un horno convencional. Los resultados correspondientes a la resistencia al desgaste han confirmado que esta propiedad está influenciada por varios factores tales como el método y temperatura de sinterización, las esferas utilizadas como contramaterial y las cargas aplicadas durante el test. Los resultados finales indicaron que los nanocomposites de Al2O3-5vol.%NbC obtenidos mediante SPS tienen un gran potencial para las distintas aplicaciones industriales, las cuales re-quieren materiales de alto rendimiento mecánico y al desgaste.

Spark Plasma Sintering

Alumina-carbeto de nióbio

Desgaste esfera no disco

Micro-ondas

Moagem reativa de alta energia

Nanocompósitos

Alúmina-carburo de niobio

Desgaste tribológico

Microondas

Molienda reactiva de alta energía

Nanocomposites

Spark Plasma Sintering

Densification Mechanisms for Spark Plasma Sintering in Alumina and Alumina Based Systems

Chakravarty, Dibyendu

January 2013

The densification mechanisms of polycrystalline α-alumina by spark plasma sintering are highly contradictory, with different research groups suggesting diffusion to dislocation controlled mechanisms to be rate controlling. The specific objective of this work was to investigate densification mechanisms of α-alumina during the intermediate and final stages of sintering by SPS, analyze the microstructural development and establish sintering trajectories. In addition, zirconia and yttria were added in different weight percentages to study the effect of solute concentration on the densification kinetics of spark plasma sintered alumina. The present work adopts a different approach from the classical method adopted previously to analyze the sintering kinetics and densification mechanisms of alumina in SPS, although existing models for hot pressing were adopted for the basic analysis. The densification behavior was investigated in the temperature range 1223-1573 K under applied stresses of 25, 50 and 100 MPa and grain sizes between 100 and 250 nm. The SEM micrographs reveal equiaxed grains with no abnormal grain growth in the dense samples. The ‘master sintering curve’ shows grain size to be primarily dependent on density, irrespective of the applied stresses or temperature. The stress exponent of 1 along with an inverse grain size exponent of 3 and activation energy of 320-550 kJ mol-1 suggests Al3+ grain boundary diffusion as the rate controlling densification mechanism in alumina. The densification rates are marginally slower in compositions with 0.1% Y2O3 and ZrO2 content possibly due to the smaller grain sizes used in this study which leads to faster rates compared to earlier reports. However, higher Y2O3 and ZrO2 content led to decrease in densification rate by more than an order of magnitude possibly due to presence of a second phase which increases the effective path length for diffusion, thereby reducing the densification rates. Presence of Y2O3 and ZrO2 in the compositions with 0.1% Y2O3 and ZrO2 were confirmed by TEM studies. The Y3Al5O12 (YAG) phase developed between 1223 and 1273 K and suppressed densification and grain growth in alumina. In spite of higher temperatures required for alumina-YAG and alumina-zirconia composites to attain density ~99%, the alumina grain size in the composites was smaller than that in pure alumina due to the Zener drag effect. The stress exponents obtained for Y2O3 and ZrO2 composites at both the concentrations yield a value of n~ 2, which indicates a change in densification mechanism from pure alumina. The higher stress dependence of these composites could be due to presence of solute and second phase formation, both of which retard densification rates. The inverse grain size exponents obtained are between 1 and 2; both stress exponent and grain size exponent values suggest an interface reaction controlled diffusion mechanism occurring in these composites, independent of the Y2O3 and ZrO2 content. Higher activation energies are obtained with the Y2O3 and ZrO2 composites of higher content, respectively, due to presence of second phase particles at grain boundaries. The presence of solutes at grain boundaries hinders grain boundary diffusion of alumina, leading to interface reaction controlled process; this is confirmed by superimposing standard aluminum grain boundary and lattice diffusion data on to stress-densification rate data obtained in this work. A comparison of stress exponents using current experimental data adopting the present and the classical approaches show a wide difference in their values indicating a change in the rate controlling diffusion path, necessitating a review of the assumptions made on the basic equations used in previous SPS studies.

Sintering

Spark Plasma Sintering (SPS)

Alumina - Densification

Pulsed Electric Current Sintering (PECS

Hot Pressing

Hot Pressing Models

Alumina - Spark Plasma Sintering

Alumina-Yttria Composites

Alumina-Zirconia Composites

Alumina - Sinterng Trajectories

Sintering Models

Polycrystalline α-alumina

Materials Science

Fuel Filim Visualization And Measurement In The Inlet Manifold Of A Carbureted Spark-Ignition Engine

Prabhu, Nishikant Madhusudan

10 1900

In order to meet future emission norms for small carbureted SI engines, such as those used on motorcycles in India, there is a need to study mixture preparation, specifically the two-phase flow exiting the carburetor and entering the inlet manifold. A fully functional, modular experimental rig is designed and erected for performing both qualitative and quantitative flow visualization. The vibrations of the engine are minimized to reduce their effect on the flow. A special, optically accessible tube of square cross-section is added between the carburetor and the inlet manifold, to enable the visualization of flow at the exit of the carburetor. An electronic circuit to obtain a signal for the engine crank angle and convert it to a standard TTL pulse, for use on standard imaging systems to capture cycle resolved-images is also designed. The flow in the optical section is qualitatively visualized using high and low speed cameras. The resulting images and movies show two modes of fuel transport within the inlet manifold, one of which is in the form of a dense cloud of fine fuel droplets during some part of the intake stroke. The second mode is in the form of a film at all times in the cycle, along the lower surface of the inlet manifold during idling and along vertical walls under loaded conditions. Recirculation is seen on the vertical walls of the manifold during idling and under load. Finally, the thickness of the fuel film in the optical section at the exit of the carburetor is measured, using PLIF. This part of the study also reveals that there is a film on upper surface of the optical section, at all loads and speeds. This film is lesser than the resolution of measurement for low loads, and increases to 0.5 mm in the case of highest load and speed attained at full throttle. In contrast to the loaded conditions, during idling, the film occurs on the lower surface of the manifold and its thickness is highest (1 mm.). The film is also present throughout the cycle during idling and all load-speed conditions, suggesting that the mixture that goes into the engine has a significant part of fuel in liquid form.

Spark-Ignition Engine - Inlet

Fuel (Machine Engineering)

Motorcycles

Flow Visualization

Carbureted Engines - Fuel Transport

Carbureted Spark-Ignition Engines

Engine-Inlet

PLIF

Fuel Filim Visualization

Automobile Engineering

ZnSe ceramics and phosphate glasses for optical applications in the visible and infrared ranges / Céramiques de ZnSe et verres de phosphate pour des applications optiques dans le visible et l'infrarouge

Zhou, Gang

21 October 2014

Une étude en deux parties a été effectuée sur la préparation et la caractérisation de céramiques de ZnSe et de verres de phosphate à des fins optiques. Pour préparer des poudres de ZnSe, deux voies de synthèse ont été utilisées: i) hydrothermales; ii) le broyage à billes. La taille des particules ainsi que leur morphologie a été analysée par différentes techniques (DRX, MEB…). Ensuite, deux technologies de frittage, pressage à chaud (HP) et frittage flash (SPS), ont été mises en œuvre pour obtenir des échantillons massifs de ZnSe optiquement transparents. La meilleure transmission obtenue dans le domaine du moyen infrarouge, pour les échantillons HP et SPS, est supérieure à 50% et 40% respectivement. Pour obtenir des verres de phosphate avec une grande durabilité chimique, des cations avec une intensité de champ élevée tels que Nb5+ et Ti4+ ont été incorporés dans un verre de phosphate. La transparence dans le domaine du visible a été obtenue en utilisant de petites quantités d'agents d'oxydation tels que les sulfates ou les nitrates. L’utilisation de la spectroscopie par réflectance diffuse a permis de déterminer les coordonnées chromatiques afin d’évaluer le bénéfice de ces ajouts. / A two-part study was conducted on the preparation and characterization of ZnSe ceramic and phosphate glasses for optical applications in the visible and infrared range. To prepare ZnSe powders, two synthetic routes were used: i) hydrothermal; ii) ball milling. The size and morphology of synthesized powders were analyzed using different techniques (XRD, SEM…). Then two sintering technologies, hot pressing (HP) sintering and spark plasma sintering (SPS) sintering have been implemented to obtain optically transparent ZnSe bulk samples. The best transmission obtained in the mid-infrared range, using HP and SPS, is greater than 50% and 40% respectively. To synthesize phosphate glasses with a high chemical durability, cations with high field strength such as Nb5+ and Ti4+ were incorporated into a phosphate matrix. The transparency in the visible range was obtained using small amounts of oxidation agents such as sulfates or nitrates. The use of diffuse reflectance spectroscopy led to determination of the chromaticity coordinates to evaluate the benefit of these additions.

Céramique

Verres de phosphates

Infrarouge

Synthèse par voie hydrothermale

Mécanosynthèse

Hot-Pressing

Spark plasma sintering

Durabilité chimique

Coordonnées de chromaticité

Ceramic

Phosphate glasses

Infrared

Hydrothermal synthesis

Ball milling

Hot-Pressing

Spark plasma sintering

Chemical durability

Chromaticity coordinates

Décharges Sparks dans les liquides diélectriques : caractérisation et application à la synthèse de nanoparticules

Merciris, Thomas

07 1900

Ce projet de recherche s’inscrit dans le parcours international de la maitrise de Physique (option plasma) de l’Université de Montréal en collaboration avec l’Université Paul Sabatier de Toulouse (France). Il concerne la caractérisation des décharges électriques (Sparks) dans les liquides diélectriques et ses applications dans la synthèse de nanoparticules. L’objectif est d’amélioré la connaissance des conditions de formation des nanoparticules. Cela implique de caractériser l’ensemble du système expérimental et de développer sa métrologie d’une part, et d’autre part d’obtenir l’évolution des paramètres plasma lors de la synthèse. Dans un premier temps, sur le site du LAPLACE (UMR5213), Toulouse, il a fallu développer une alimentation électrique impulsionnelle destinée à réaliser des décharges dans les liquides. En se basant sur un dispositif existant qui fût amélioré, le fonctionnement a été caractérisé du point de vue électrique (courant - tension). L’application à la synthèse de nanoparticules a été ensuite abordée pour différentes conditions expérimentales, en considérant l’aspect énergétique (bilan d’énergie, caractéristiques de la décharge…). Les travaux se sont poursuivis à l’Université de Montréal, où un circuit électrique équivalent du système expérimental est réalisé afin de visualiser l’évolution temporelle des paramètres plasma (température et densité électronique) en fonction des paramètres électriques choisis. Aussi, la synthèse de nanoparticules de Co et Ni par la décharge a été évaluée et les nanoparticules formées sont caractérisées à l’aide du microscope électronique à Transmission de Polytechnique Montréal. / This research project is part of the international master's program in Physics (plasma option) between Université de Montréal and Université Paul Sabatier - Toulouse (France). It concerns the synthesis of nanoparticles by pulsed electrical discharges in liquids. The objective is to develop the synthesis process while improving the knowledge of the formation conditions of nanoparticles. This involves characterizing the entire experimental system and developing its metrology on the one hand, and on the other hand obtaining the evolution of plasma parameters during synthesis. Initially, at the LAPLACE lab (UMR5213), Toulouse, it was necessary to develop a pulsed electrical supply to produce discharges in liquids. Based on an existing device that, after being improved, the discharge process is characterized from the electrical point of view (current, voltage). The application of the device in the synthesis of nanoparticles was tested under different experimental conditions, considering the energy aspect (energy balance, characteristics of the discharge, etc.). The second part was conducted at Université de Montréal, where the synthesized nanoparticles are characterized using the transmission electron microscope of Polytechnique Montreal. Also, the electrical circuit equivalent to the experimental system was determined to visualize the time evolution of the plasma parameters (Temperature and Electron Density) based on the electrical characteristics.

Nanoparticules

Décharges Spark

Circuits équivalents

Nickel

Cobalt

Cavitation

Nanoparticles

Spark discharge

Equivalents circuits

High voltage pulsed power supply

Vysoce entropické slitiny Cantorova typu zpevněné disperzí nitridů / Nitride dispersion strengthened Cantor´s high entropy alloys

Havlíček, Štěpán-Adam

January 2020

High Entropy Alloy (HEA) is a class of construction steels based on the mixing of five or more elements in approximately equimolar ratios. Despite the ambiguity of their future use, HEAs represent a significantly new group of construction materials that are currently receiving a great deal of attention. Single-phase HEAs fail when used at elevated tempera-tures. The improvement of their high-temperature resistance was achieved by introducing a dispersion of oxides Al2O3 and Y2O3. To generalize the positive effect of dispersions on the mechanical properties at elevated temperatures, particles of a similar nature were cho-sen. These were dispersed particles of nitrides: hardness-incompatible AlN and hardness-compatible BN. The particles were evenly distributed inside the alloys by mechanical al-loying and compacted by SPS (Spark Plasma Sintering). The new structural alloy reached a density higher than 96.5 % and brought an increase in yield strength at room tempera-ture of up to 67 % and 40 % at elevated temperatures, while maintaining a homogeneous distribution of input powders.

Particules d'acier nitrurées : étude de la densification et caractérisations microstructurales des matériaux frittés à vocation tribologique / Nitrided steel particles : densification study and microstructural characterizations of sintered materials for tribological application

Jolly, William

28 May 2013

L'objectif de ce travail de thèse consistait à développer d'une technologie de mise en forme de poudres d'aciers faiblement alliés nitrurées afin d'introduire le nitrure ε-Fe2-3N dans la masse de la pièce mécanique.Pour atteindre cet objectif, deux voies ont été étudiées :- réaliser des pièces frittées à partir de poudre d'acier nitrurée ou nitrurée-enrobée (contenant une teneur importante en nitrure ε),- nitrurer et densifier une poudre d'acier pendant l'étape de frittage.La nitruration d'une poudre d'acier 4140 lors du frittage en CIC s'est avérée insuffisante vis-à-vis des teneurs en nitrure ε nécessaires pour l'application industrielle.L'étude de la stabilité, en CIC, de la poudre d'acier 4140 nitrurée a démontré la conservation des nitrures γ' et ε en grande proportion jusqu'à des températures de 650°C, quel que soit la nature du cycle de CIC appliqué. L'étude de la stabilité, à 600°C, de poudres d'acier nitrurées placées en capsules scellées a montré une légère dénitruration de ces poudres pendant le traitement.Des essais de densification de ces poudres d'acier nitrurées ont ensuite été réalisés par frittage SPS puis CIC. Afin de densifier les particules d'acier nitrurées, nous avons choisi d'utiliser un liant. Les essais de frittage SPS ont permis de mettre en évidence les paramètres expérimentaux les plus pertinents pour l'obtention d'un matériau dense et comportant le nitrure ε, et de proposer des préconisations sur les compositions acier-liant. Ces compositions ont été testées en CIC avec succès. Deux d'entre elles ont ainsi permis l'obtention de matériaux denses aux propriétés tribologiques et mécaniques satisfaisantes pour l'application industrielle. / The aim of this Ph.D thesis was to develop a technology to shape nitrided low-alloyed steels powders to introduce the ε-Fe2-3N nitride in the volume of the mechanical component.To achieve this goal, two approaches were considered:- the sintering of coated nitrided steel powder or nitrided steel powder (containing a high content of ε nitride),- the simultaneous densification and nitriding of low-alloy steel powder during the sintering step.Nitriding 4140 steel powder during hot isostatic pressing (HIP) does not allow producing sufficient ε-phase content for industrial application.The stability study of nitrided 4140 steel powder during HIP shows that a huge proportion of nitrides (γ' and ε) is conserved at 650°C, regardless of the HIP cycle. The stability study, at 600°C, of nitrided steel powders placed in sealed evacuated glass tubes, shows a slight denitriding of these powders during the process.Thus, densification of these nitrided steel powders was made by spark plasma sintering (SPS) and HIP. To densify the nitrided steel particles, we have used a copper-phosphorous binder. From SPS experiments, we have deduced the most relevant experimental parameters to obtain a dense material containing ε-phase, and we have proposed recommendations on the composition of nitrided steel-binder mixture. The identified compositions were successfully sintered by HIP. Two of them allow obtaining dense materials with interesting tribological and mechanical properties for industrial application.

Métallurgie des poudres

Acier nitruré

Densification

Frittage

Compression isostatique à chaud (CIC)

Spark Plasma Sintering (SPS)

Nitrure ε

Dénitruration

Powder metallurgy

Nitrided steel

Densification

Sintering

Hot isostatic pressing (HIP)

Spark plasma sintering (SPS)

Ε iron nitride

Denitriding

671.3

Mikroskopische Aspekte beim feldaktivierten Sintern metallischer Systeme

Trapp, Johannes

20 February 2017

1. Beim feldaktivierten Sintern im Temperaturbereich von 500 bis 1000 °C fließen elektrische Ströme mit einer Dichte von 1 bis 3 A/mm². 2. Daraus folgt für die größten verwendeten Pulverteilchen mit einem Radius von 50 µm ein Strom je Teilchenkontakt von 10 bis 50 mA. 3. Die durch das Aufbringen des prozesstechnisch notwendigen Pressdruckes gebildeten relativen Kontaktradien (Kontaktradius geteilt durch Teilchenradius) haben eine Größe von 0,05 bis 0,3. 4. Die Einengung der Strompfade im Kontakt der Pulverteilchen erhöht, zusammen mit dem elektrischen Widerstand der Oxidschicht auf den Pulverteilchen, den elektrischen Widerstand des Pulverpresslings. 5. Der Stromfluss durch die Teilchenkontakte führt mit dem zusätzlichen elektrischen Widerstand dieser Teilchenkontakte zu einer lokalen Temperaturerhöhung (Übertemperatur) von 10-4 bis 1 Kelvin für Kupfer- respektive Stahlpulver. 6. Der zusätzliche elektrische Widerstand der Oxidschicht kann die Übertemperatur beim Kupferpulver auf bis zu 1 mK erhöhen. 7. Mit abnehmendem Teilchenradius sinkt die Übertemperatur quadratisch. 8. Das Wachstum der Teilchenkontakte im Verlauf der Verdichtung führt zu einer kontinuierlichen Verringerung der Übertemperatur. 9. Das Auftreten von schmelzflüssiger Phase, von Metalldampf oder von Plasma wird in den untersuchten metallischen Systemen ausgeschlossen. 10. Auch Elektromigration, Thermomigration oder andere Wirkungen des elektrischen Stromes spielen keine Rolle für die Verdichtung beim feldaktivierten Sintern. 11. Die Verwendung von gepulstem anstelle von kontinuierlichem Gleichstrom beeinflusst die Verdichtung der untersuchten Werkstoffe nicht. 12. Die Verdichtung vom Pulver zum kompakten Werkstoff findet für Pulverteilchen mit einem Radius größer als R = 10 µm über plastische Verformung durch verschiedene Formen des Kriechens statt. 13. Die Verformung ist im Anfangsstadium auf den Kontaktbereich begrenzt. 14. Bei Pulverteilen mit Teilchenradien unter R = 10 µm findet die Verdichtung zunächst als Folge von Leerstellenströmen in die Kontaktkorngrenze statt (Sintern). 15. Durch die schnelle Verdichtung bei niedriger homologer Temperatur werden Kornwachstum und Rekristallisation verringert.

info:eu-repo/classification/ddc/624

ddc:624

Hochdruck–Hochtemperatur–Synthese und Charakterisierung tetrelreicher Seltenerdmetallverbindungen und Darstellung von Ba8Ga16±xGe30∓x mittels Spark–Plasma–Sinterverfahren

Meier, Katrin

29 October 2012

In dieser Dissertation wird die Darstellung tetrelreicher Seltenerdmetall–Verbindungen in den Systemen SE:Tt (SE = La, Nd, Sm, Gd, Tb, Ho, Lu; Tt = Si, Ge) und die Charakterisierung ihrer Eigenschaften beschrieben. Diese Verbindungen, welche mittels der Hochdruck–Hochtemperatur–Methode dargestellt wurden, zeigen neuartige Verknüpfungsmuster in der Tetrel–Partialstruktur. Neben der Charakterisierung der Verbindungen hinsichtlich der thermischen Stabilität und der physikalischen Eigenschaften bei Normaldruck wurde bei den Germanium–reichen Seltenerdmetall–Verbindungen eine Untersuchung der Veränderungen der Kristallstruktur bei Variation des Drucks oder der Temperatur vorgenommen. Die dargestellten Seltenerdmetall–Trisilicide SESi3 (SE = Gd, Ho, Lu) kristallisieren tetragonal isotyp zu YbSi3. LuSi3 zeigt Supraleitung mit Tc = 7.0 K. In den Systemen Gd–Si und SE–Ge (SE = La, Nd, Sm, Gd, Tb) wurden die Verbindungen GdSi5 und SEGe5 (SE = La, Nd, Sm, Gd, Tb) synthetisiert. Sie kristallisieren orthorhombisch isotyp zu LaGe5. Durch in–situ Röntgenbeugungsexperimente bei erhöhten Temperaturen kann die Existenz metastabiler Germanium–ärmerer Verbindungen SE2Ge9 (SE = Nd, Sm) nachgewiesen werden. Es handelt sich um Defektvarianten der Verbindungen SEGe5 (SE = Nd, Sm). Die strukturelle Verwandtschaft zum Aristotyp SEGe5 wird anhand einer Gruppe–Untergruppe–Beziehung aufgezeigt. Eine alternative Synthesemethode zur Darstellung tetrelreicher Verbindungen mit Gerüststrukturen bei extremen Reaktionsbedingungen stellt das Spark–Plasma–Sinterverfahren (SPS) dar. Die Darstellung der Clathratphase Ba8Ga16±xGe30∓x (x = 0, 1) erfolgte mittels SPS aus den Precursoren BaGa2±x (x = 0, 0.125) und Germanium. Die Untersuchungen der thermoelektrischen Eigenschaften zeigen, dass durch Variation der nominellen Zusammensetzung sowohl n–leitende als auch p–leitende Eigenschaften erhalten werden können. / In this thesis the synthesis of tetrel–rich rare–earth metal compounds in the systems RE:Tt (RE = La, Nd, Sm, Gd, Tb, Ho, Lu; Tt = Si, Ge) and the characterization of their properties is described. These compounds, synthesized by means of high–pressure high–temperature method, show new structural motifs in the tetrel partial structure. The compounds were characterized with respect to their thermal stability and their physical properties at ambient pressure. In addition, the changes in the crystal structure of the germanium-rich rare–earth metal compounds by variation of pressure or temperature were investigated. The synthesized rare–earth trisilicides SESi3 (SE = Gd, Ho, Lu) crystallize tetragonal, isotypic to YbSi3. LuSi3 is a superconductor with Tc = 7.0 K. In the systems Gd–Si and SE–Ge (SE = La, Nd, Sm, Gd, Tb) the compounds GdSi5 and SEGe5 (SE = La, Nd, Sm, Gd, Tb) were synthesized. They crystallize orthorhombic isotypic to LaGe5. Using in-situ high–temperature X-ray experiments the metastable germanium-poorer compounds SE2Ge9 (SE = Nd, Sm) could be observed. These compounds are defect variants of the pentagermanides SEGe5 (SE = Nd, Sm). The structural relationship to the aristotype SEGe5 is given via a group-subgroup relation. An alternative synthesis route for the preparation of tetrel–rich compounds with framework structures at extreme reaction conditions is the spark plasma sintering method (SPS). The clathrate phase Ba8Ga16±xGe30∓x (x = 0, 1) was synthesized from the precursors BaGa2±x (x = 0, 0.125) and germanium by means of SPS. The investigation of the thermoelectric properties shows, that through variation of the nominal composition both n-type and p-type conduction properties can be obtained.

info:eu-repo/classification/ddc/540

ddc:540