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101	Elaboration et étude des conditions de mise en forme de poudres composites métalliques pour des pièces industrielles à vocation électromagnétiques / Elaboration and shaping of composite particles for electromagnetic industrial pieces Guicheteau, Rudy 18 March 2015 (has links) Le développement des moteurs électromagnétiques nécessite des matériaux magnétiques possédant une forte induction à saturation, une perméabilité magnétique importante, ainsi que de faibles pertes magnétiques lorsque le matériau est utilisé à des fréquences allant jusqu’à 20 kHz.Pour réduire ces pertes, le matériau doit alors posséder une résistivité électrique la plus élevée possible. Les composites magnétiques doux ont été développés dans ce contexte, en associant du fer (ou un alliage) à un matériau isolant. Historiquement, ceux-ci étaient présents sous forme de couches laminées, mais des matériaux coeur-écorce se sont développés ces dernières années.Au cours de ces travaux, nous avons développé l’enrobage de particules de fer par un matériau isolant et magnétique : le ferrite NiZn. L’enrobage de ferrite a été réalisé par voie liquide. De cette manière, il a été possible de réaliser un enrobage homogène d’épaisseur contrôlée sur des particules de fer sphériques.L’étude de la mise en forme de ces particules coeur-écorce, par métallurgie des poudres, a montré qu’en frittant le matériau composite à une température supérieure à 580°C, une réaction d’oxydoréduction a lieu entre les deux composés. Cette réaction mène à la formation d’une phase type FexNi1-x et d’une solution solide FeO-FeZnO. Ces deux phases font alors chuter les propriétés magnétiques du matériau final.Pour éviter cette réaction d’oxydoréduction, nous avons montré qu’il est possible d’ajouter une barrière de diffusion : la silice, ou bien de fritter le matériau à l’aide de techniques type FAST. De cette manière, nous avons obtenu un matériau possédant des pertes magnétiques comparables à celles de poudres industrielles mais avec une perméabilité magnétique supérieure. / Magnetic materials with high saturation induction, high magnetic permeability and low magnetic losses, are necessary for the development of electromagnetic motors used at frequencies up to 20 kHz.The electric resistivity of these materials must be as high as possible to reduce iron losses. To increase the resistivity of ferromagnetic materials, soft magnetic composites (SMC) were developed combining a ferromagnetic material with an insulating one. Firstly, laminated steel sheets were developed but during the last years core-shell materials were investigated.In this work, we have studied the coating of iron particles by an insulating and a magnetic material: NiZn ferrite. These coatings were deposited by an aqueous solution to obtain a homogenous coating with a controlled thickness on spherical iron particles.A study of composite shaping by powder metallurgy shows a redox reaction between ferrite and iron at a sintering temperature above 580°C. This reaction leads to the formation of a FexNi1-x and a FeO-FeZnO solid solution. These two phases deteriorate the magnetic properties of the final material.To avoid this redox reaction, we have shown that a silica layer can be used as a diffusion barrier. Another solution is to sinter the composite with a Field Assisted Sintering Technique (FAST) as Spark Plasma Sintering. A material with properties similar to industrial material and with a superior magnetic permeability was obtained with Spark Plasma Sintering Composite magnétique doux Coeur-écorce Ferrite Frittage flash Barrière de diffusion Silice SMC Soft Magnetic composite (SMC) Core-shell Ferrite Spark Plasma Sintering (SPS) Diffusion barrier Silica 620.118
102	Sinterização de cerâmicas multiferróicas nanoestruturadas de Pb(Fe1/2Nb1/2)O3 e Pb(Fe2/3W1/3)O3 via Spark Plasma Sintering SPS Nascimento, William Junior do 25 February 2013 (has links) Made available in DSpace on 2016-06-02T20:15:28Z (GMT). No. of bitstreams: 1 5160.pdf: 6005480 bytes, checksum: 6aae866e51fab054ffc455e4b0479f2f (MD5) Previous issue date: 2013-02-25 / Financiadora de Estudos e Projetos / Considering the search for miniaturization of electronic devices, the development of new methods and techniques for the production and characterization of nanostructured materials is fundamental, beyond understanding of the effect of grain size on the properties of materials in nanoscale. Therefore, it was proposed in this work the obtaining of nanostructured multiferroic materials, in bulk, with high density and microstructural control, with grains ranging from micrometer to nanometer scale. To achieve this goal, was developed a methodology for obtaining the powder of lead iron niobate, Pb(Fe1/2Nb1/2)O3 (PFN) and lead iron tungstate, Pb(Fe2/3W1/3)O3 (PFW), with average particle size around 150 nm, contamination-free, minimal agglomeration and with highly reproductive results using the micro-milling technique. Regarding consolidation materials, conventional sintering requires higher temperatures and long holding times for a satisfactory densification, resulting in a grain growth higher than the desired. Through the fast sintering technique, only high heating rates are not sufficient to ensure a satisfactory densification and also inhibit the growth of grains. The obtain nanostructured dense samples with average grain size of approximately 200 nm was only possible using spark plasma sintering technique (SPS), which allows sintering at temperatures corresponding to the intermediate sintering stage, inhibiting the grain growth. PFN and PFW samples obtained through the SPS technique showed high conductivity at room temperature due the extreme reduction suffers in the system plus the use of high current densities during sintering, being necessary the samples oxidation. Through the dielectric characterization, the decrease in grain size of micrometer to nanometer scale results in lower permittivity values in phase transition temperature, besides a peak broadening. Moreover, the SPS technique added to the oxidation process makes it possible to obtain PFW samples with high dielectric values (in order of 104) at room temperature, a motivation results with regard to the application. / Considerando a busca pela miniaturização dos dispositivos eletrônicos é fundamental o desenvolvimento de novos métodos e técnicas para a produção e caracterização de materiais nanoestruturados, além do entendimento do efeito do tamanho de grão sobre as propriedades dos materiais em escala nanométrica. Dessa forma, propôs-se neste trabalho a obtenção de materiais multiferróicos nanoestruturados, na forma de bulk com alta densidade e controle microestrutural, com grãos variando de escala micrométrica a nanométrica. Para alcançar este objetivo, foi desenvolvida uma metodologia para a obtenção de pós de niobato de ferro e chumbo, Pb(Fe1/2Nb1/2)O3 (PFN) e tungstanato de ferro e chumbo, Pb(Fe2/3W1/3)O3 (PFW), com tamanhos médios de partículas em torno de 150 nm, livre de contaminação, mínima aglomeração e com resultados altamente reprodutivos por meio da técnica de micromoagem. Em relação à consolidação dos materiais, o procedimento convencional requer altas temperaturas e longos tempos de patamar para uma densificação satisfatória, resultando em um crescimento de grão superior ao desejado. Por meio da técnica de sinterização rápida fast sintering , somente altas taxas de aquecimento não são suficientes para garantir uma densificação satisfatória bem como inibir o crescimento de grãos. A obtenção de amostras densas nanoestruturadas com tamanhos médio de grão de aproximadamente 200 nm só foi possível utilizando a técnica spark plasma sintering (SPS), que permite a sinterização a temperaturas correspondentes ao estágio intermediário de sinterização, inibindo o crescimento de grãos. As amostras de PFN e PFW obtidas por meio da técnica de SPS apresentaram alta condutividade à temperatura ambiente devido às condições extremas de redução que a amostra sofre somada ao uso de altas densidades de corrente durante a sinterização, sendo necessária a oxidação das mesmas. Através da caracterização dielétrica, verifica-se que a diminuição nos tamanhos de grãos de escala micrométrica para nanométrica resulta em menores valores de permissividade na temperatura de transição de fase, além de um alargamento dos picos. Contudo, a técnica de sinterização SPS somada ao processo de oxidação torna possível a obtenção de amostras de PFW com altos valores de constate dielétrica (na ordem de 104), a temperatura ambiente, resultado extremamente motivador no que diz respeito à aplicação. Física do estado sólido Cerâmicas multiferróicas Materiais nanoestruturados Niobato de ferro e chumbo (PFN) Nanostructured ceramics Spark Plasma Sintering PFN PFW CIENCIAS EXATAS E DA TERRA::FISICA
103	Elaboration par Spark Plasma Sintering et caractérisation de composites et multi-couches zircone yttrié/MoSi2(B) pour application barrière thermique auto-cicatrisante / Elaboration by Spark Plasma Sintering and characterization of yttria partially stabilized zirconia/MoSi2(B) composites and multi-layer systems for self-healing thermal barrier coatings Nozahic, Franck 28 November 2016 (has links) La réparation des revêtements barrières thermiques endommagés par fissuration entraine des coûts de maintenance très élevés. Dans cette étude, qui s’inscrit dans le cadre du projet Européen FP7-SAMBA, il a été proposé d’utiliser des particules de MoSi2(B), revêtues d’une couche d’alumine, comme agent cicatrisant. L’oxydation de celles-ci doit entrainer la formation de silice amorphe qui s’écoule dans la fissure puis réagit avec la barrière thermique en zircone yttriée pour former du zircon. Cette étude traite dans un premier temps de l’élaboration par Spark Plasma Sintering (SPS) de composites modèles composés de zircone yttriée et de particules de MoSi2(B) non revêtues. Les propriétés mécaniques (ténacité, dureté, module d’Young) et thermiques (conductivité thermique, coefficient de dilatation) de ces composites ont été déterminées. Les travaux se sont ensuite orientés vers l’étude du comportement en oxydation cyclique à 1100 °C sous air de ces composites par thermogravimétrie cyclique. La modélisation de l’oxydation de ces composites mais aussi de systèmes multi-couches MoSi2(B)/YPSZ modèles a permis de déterminer les mécanismes et les cinétiques de formation de la silice et du zircon. Une augmentation significative des cinétiques de formation de ces oxydes a été observée lorsque le bore est ajouté dans le MoSi2 ce qui peut être potentiellement très bénéfique pour la cicatrisation des fissures. L'utilisation du procédé SPS a permis de réaliser des systèmes barrières thermiques auto-cicatrisants sur substrats en superalliages à base de nickel revêtus à partir de zircone yttriée et de particules de MoSi2(B) elles-mêmes revêtues d’une couche d’alumine. La pré-oxydation des substrats revêtus favorise la croissance d’une couche d’alumine qui empêche la formation de siliciures par réaction entre les particules et la sous-couche. Ces revêtements présentent une bonne résistance à l’endommagement en cyclage thermique. Les observations post-mortem de ces systèmes mettent en évidence la cicatrisation locale de fissures par formation de silice et de zircon. Bien qu’il ne soit pas possible aujourd’hui de dire si la présence de ces particules augmente ou non la durée de vie de la barrière thermique, par manque de systèmes de référence, ces observations très encourageantes démontrent expérimentalement la validité du concept d’auto-cicatrisation des barrières thermiques proposé dans le cadre de ce projet. / Repair of thermal barrier coatings (TBC) systems damaged by cracking leads to significant maintenance costs. In this project (FP7-SAMBA), it was proposed to use MoSi2(B) particles, coated with an alumina shell, as healing agent for TBCs. Healing particles intercepted by cracks will oxidize preferentially, leading to the formation of amorphous SiO2, which flows into cracks and subsequently reacts with the TBC leading to the formation of a load bearing ZrSiO4 phase. In this study model composite materials were prepared from mixtures of yttria partially stabilized zirconia (YPSZ) and uncoated MoSi2(B) particles by using Spark Plasma Sintering (SPS) technique. Mechanical (toughness, hardness, Young modulus) and thermal (conductivity, coefficient of thermal expansion) properties of these materials were determined. Then, cyclic thermogravimetry analysis (CTGA) was used to study the oxidation behavior of these materials at 1100 °C in air. Kinetics of silica and zircon formations were determined through modelling of the oxidation of composite materials but also the oxidation of multi-layer YPSZ/MoSi2(B) materials. Boron addition was shown to significantly increase silica and zircon formation rates which could be very beneficial for the healing of the cracks. Then, SPS technique was used to sinter self-healing thermal barrier coatings on bond coated Ni-based superalloys from mixtures of YPSZ and Al2O3-coated MoSi2(B) particles. The pre-oxidation of coated substrates was shown to prevent the detrimental formation of silicides by the reaction of MoSi2(B) particles and the bond coat. Good results were obtained upon thermal cycling and post-mortem observations highlight local healing of cracks. At this time, it is too early to quantify the potential effect of the particles on the TBC lifetime due to a lack of reference systems and statistics. However, these observations demonstrate, experimentally, the validity of the self-healing mechanism proposed in the framework of this project. Composites YPSZ/MoSi2 Système barrière thermique Frittage Flash Oxydation haute température Auto-cicatrisant Composites YPSZ/MoSi2 Thermal barrier coatings Spark Plasma Sintering High temperature oxidation Self-healing
104	Investigações sobre a sinterização de sílica vítrea por plasma pulsado. / Investigations of vitreous silica sintering by spark plasma. Bruno Barazani 30 June 2011 (has links) A obtenção da sílica vítrea pelo processo de sinterização por plasma pulsado (SPS), a partir de matérias-primas de diferentes estruturas (cristalina e amorfa) e diferentes granulometrias, foi investigada. Análises de difração de raios X, transmitância óptica, microscopia óptica e eletrônica de varredura, e medições de densidade foram realizadas nas amostras sinterizadas. Sílicas vítreas transparentes foram fabricadas a partir de pós de quartzo atingindo-se temperaturas finais entre 1450 e 1600°C, enquanto que nanopó e pó amorfo de sílica formaram consolidados transparentes com temperaturas máximas próximas de 1200° C. Taxas de aquecimento entre 40 e 150°C/min. foram utilizadas nas sinterizações, com tempos de processo menores que 40 minutos. As maiores taxas de aquecimento exigiram uma maior temperatura final para a fusão completa do material cristalino e causaram, de forma indireta, a presença de aglomerações de micro-bolhas nas amostras obtidas com o nanopó. Um gradiente radial de temperatura (decrescente do centro para as bordas) foi observado nos consolidados fabricados com os pós cristalinos, facilitando o processo de fechamento da porosidade aberta. A presença ou ausência de material não fundido e de bolhas nas amostras foram analisadas por difratogramas de raios X, microscopia óptica e medidas de densidade. A análise da transmitância indicou uma quantidade praticamente nula de grupos OH nos compactos sinterizados com os pós cristalinos e em torno de 20 ppm no caso dos sólidos fabricados com matéria-prima sol-gel. Amostras de nanopós de sílica dopada com titânia (~6% em massa) foram processadas com temperaturas finais de 1200 e 1400°C apresentando coloração azulada e negra, respectivamente, e aumento dos clusters de titânia para a temperatura mais elevada. A sinterização a uma temperatura em torno 1200°C mantida por apenas 4 minutos resultou na conversão completa da fase anatase para a fase rutilo da titânia. / The production of vitreous silica by the spark plasma sintering (SPS) process, starting from raw materials of different structures (crystalline and amorphous) and granulometry were investigated. Analysis of X-ray diffraction, optical transmittance, optical and scanning electron microscopy, and density measurements were performed on the sintered compacts. Transparent vitreous silica was fabricated from quartz powder at final temperatures ranging from 1450 and 1600°C while silica nanopowder and silica powder formed transparent compacts at temperatures around 1200°C. Heating rates between 40 and 150° C/min. were used in processes with durations smaller than 40 minutes. Higher heating rates demanded higher final temperatures to complete the fusion process and caused, indirectly, the formation of micro-bubbles agglomerations in the samples produced from the nanopowder. A radial gradient of temperature (decreasing from the center to the border) was observed at the compacts fabricated with the crystalline powders favoring the closure of the open porosity. The presence or the absence of non-fused material and bubbles in the samples was analyzed by X-ray diffraction, optical microscopy and density measurements. The transmittance analysis indicated an almost zero quantity of OH groups in the compacts sintered from crystalline powders and about 20 ppm in the solids fabricated from the sol-gel raw material. Nanopowder samples of silica titania (~6 wt % of titania) were processed with final temperatures of 1200°C and 1400°C presenting blue and black coloration, respectively, and an increase of the titania clusters for the highest temperature. The sintering at temperatures near 1200°C with a holding time of just 4 minutes caused the complete anatase-rutile conversion in titania. Caracterização físico-química Nanopó Parâmetros de processo Quartzo Sílica vítrea Sinterização por plasma pulsado Nanopowder Physicochemical characterization Process parameters Quartz Spark plasma sintering Vitreous silica
105	Otimização e fabricação de dispositivos piezelétricos com gradação funcional de material. / Optimization and manufacturing of piezoelectric devices with functionally graded materials. Ricardo Cesare Román Amigo 18 January 2013 (has links) Cerâmicas piezelétricas possibilitam posicionamento e sensoriamento de precisão ou captação de energia mecânica valendo-se do efeito piezelétrico, capaz de converter energia mecânica em elétrica ou o contrário. Para aprimorar ou estender as aplicações dessas cerâmicas, mecanismos flexíveis podem ser acoplados a elas, formando um Dispositivo Piezelétrico Flextensional (DPF). No projeto desse tipo de estrutura, o conceito de Material com Gradação Funcional (MGF) é interessante, já que esses materiais apresentam variações graduais de suas propriedades efetivas, permitindo a alternância entre um material mais flexível e um mais rígido de acordo com a intensidade de deslocamento desejada em cada região da estrutura. Assim, neste trabalho, implementa-se o Método de Otimização Topológica (MOT) no projeto de estruturas gradadas com o intuito de identificar as vantagens e desvantagens da utilização do conceito de MGF em DPF. Esse método combina algoritmos de otimização e o Métodos dos Elementos Finitos (MEF) para distribuir material dentro de um domínio fixo através de um modelo de material, que no presente caso é o de Material Isotrópico Sólido com Penalização (MISP) adaptado a MGF. Na fabricação desses dispositivos otimizados, utiliza-se a Sinterização por Jato de Plasma (SJP) para a obtenção de tarugos gradados que são submetidos a processos de eletro-erosão e de corte a laser. Por fim, para a verificação dos resultados numéricos, utiliza-se um vibrômetro para aferir os deslocamentos dos protótipos de atuadores fabricados. / Piezoelectric devices enable precision positioning and sensing or mechanical energy harvesting based on the piezoelectric effect. In flextensional piezoelectric devices, flexible coupling structures are attached to ceramics to improve or extend the application possibilities. On the design of this kind of structure, the concept of Functionally Graded Materials (FGM) can be interesting, since it allows gradual variations of its effective properties along some direction by mixing two or more materials. Thus, in order to identify the advantages and disadvantages of using FGM, graded flexible coupling structures that maximize the performance of piezoelectric devices are obtained by implementing the Topology Optimization Method (TOM). This method combines optimization algorithms and the Finite Element Method (FEM) to distribute material inside a fixed domain. In this work, the formulation is based on the Solid Isotropic Material with Penalization (SIMP) material model adapted for the FGM concept, which can represent continuous change in material properties along the domain. Resulting optimal graded topologies of coupling structures are presented and compared with homogeneous structures. Finally, graded devices are manufactured through Spark Plasma Sintering (SPS) technique in order to be characterized, validating numerical results. The numerical results demonstrate the TOM efficacy in designing functionally graded piezoelectric devices and show, by its implementation, significant gains in graded mechanisms performance when compared with analogous homogeneous. Furthermore, the feasibility of proposed manufacturing process is confirmed, allowing the fabrication of prototypes with expected behavior. Atuadores piezelétricos Materiais com gradação funcional Método de otimização topológica Sinterização por jato de plasma Functionally graded material Piezoelectric actuators Spark plasma sintering Topology optimization method
106	Elaboration de matériaux à gradient de propriétés fonctionnelles pour les composants face au plasma des machines de fusion thermonucléaires / Elaboration of functionnally graded materials for plasma facing components of the thermonuclear machines Autissier, Emmanuel 14 November 2014 (has links) L'objectif de ce travail était d'élaborer un matériau à gradient de propriétés fonctionnelles (MGF) W/Cu afin de remplacer la couche de compliance (Cu-OFHC) dans les composants face au plasma des machines de fusion thermonucléaire de type ITER. La particularité de ce travail étant de réaliser ces matériaux sans dépasser la température de fusion du cuivre dans le but de contrôler la microstructure des matériaux. Le cofrittage est la solution la plus attractive pour les réaliser. La première étape du travail a donc été de diminuer la température de frittage du tungstène afin de réaliser ce cofrittage. La mise en forme d'un MGF continus étant délicat, des calculs thermomécaniques ont été réalisés afin de déterminer le nombre et la composition chimique des couches W-Cu pour augmenter la durée de vie des CFPs. Les conditions de frittage par Spark Plasma Sintering ont été optimisées afin d'avoir une densité maximale des monomatériaux WxCu1-x. L'influence de la teneur en cuivre et de la densité des monomatériaux sur les propriétés thermiques et mécaniques a été étudiée. Les conditions de frittage SPS des monomatériaux ont été appliquées sur des assemblages W/CuCrZr composés de plusieurs couches intercalaires. L'importance du temps d'assemblages pour l'intégrité de ceux-ci a été mise en évidence. L'étude du temps de palier lors des assemblages W/CuCrZr a permis d'identifier un paramètre permettant de qualifier l'intégrité de l'assemblage quelle que soit la composition et la nature de la couche de compliance. De plus, les phénomènes associés à la formation des interfaces de l'assemblage ont été identifiés. L'interface W/WxCu1-x est formée par l'extrusion du cuivre de la couche WxCu1-x dans les porosités du tungstène. L'interface WyCu1-y/CuCrZr est formée par la migration du cuivre de la couche CuCrZr dans la couche WyCu1-y. Enfin l'optimisation des conditions d'assemblage a montré que les contraintes mécaniques dues à la densification du Matériau à gradient de Propriétés Fonctionnelles pouvaient être limitées en frittant préalablement ce matériau. / The objective of this study was to develop a Functionally Graded Material (FGM) W / Cu to replace the compliance layer (Cu-OFHC) in the plasma facing components of thermonuclear fusion reactor like ITER. The peculiarity of this work is to elaborate these materials without exceeding the melting temperature of copper in order to control its microstructure. The co-sintering is the most attractive solution to achieve this goal.The first phase of this study has been to decrease the sintering temperature of the tungsten to achieve this co-sintering. The elaboration of a Functionally Graded Materials being delicate, thermo-mechanical calculations were performed in order to determine the number and chemical composition in order to increase the lifespan of Plasma Facing Components. Spark Plasma Sintering conditions were optimized in order to achieve maximum density of WxCu1-x composites. The effect of copper content and density of the WxCu1-x composites on thermal and mechanical properties was investigated. The SPS conditions were applied for W/CuCrZr assemblies with a compliance layer composed of several interlayers. The importance of time for the integrity of assemblies thereof has been highlighted.The study of the dwell time during W/CuCrZr assembly leads to identify a parameter to characterize the integrity of the interface regardless of the composition and the nature of the layer of compliance. Moreover, the phenomena associated with the formation of the interface assembly have been identified. The interface W/WxCu1-x is formed by the extrusion of the copper layer of the WxCu1-x inside the tungsten porosities. The WyCu1-y/CuCrZr interface is formed by copper migration of CuCrZr layer inside the WyCu1-y layer. Finally optimization assembly conditions showed that the mechanical stresses due to the densification of the Functionally Graded Materials can be limited by sintering the FGM before the assembly. Composants Face au Plasma Fusion thermonucléaire Métallurgie des poudres Spark Plasma Sintering Tungstène Cuivre Finite Element Modeling Loi des mélanges Plasma facing components 530 540
107	Graphene NanoPlatelets Reinforced Tantalum Carbide consolidated by Spark Plasma Sintering Nieto, Andy 25 March 2013 (has links) Hypersonic aerospace vehicles are severely limited by the lack of adequate high temperature materials that can withstand the harsh hypersonic environment. Tantalum carbide (TaC), with a melting point of 3880°C, is an ultrahigh temperature ceramic (UHTC) with potential applications such as scramjet engines, leading edges, and zero erosion nozzles. However, consolidation of TaC to a dense structure and its low fracture toughness are major challenges that make it currently unviable for hypersonic applications. In this study, Graphene NanoPlatelets (GNP) reinforced TaC composites are synthesized by spark plasma sintering (SPS) at extreme conditions of 1850˚C and 80-100 MPa. The addition of GNP improves densification and enhances fracture toughness of TaC by up to ~100% through mechanisms such as GNP bending, sliding, pull-out, grain wrapping, crack bridging, and crack deflection. Also, TaC-GNP composites display improved oxidation behavior over TaC when exposed to a high temperature plasma flow exceeding 2500 ˚C. Tantalum Carbide graphene graphene nanoplatelets spark plasma sintering nanocomposites ceramic matrix composites ultra high temperature ceramics high temperature oxidation fracture toughness
108	Deposition of Copper Nanoparticles on 2D Graphene NanoPlatelets via Cementation Process Da Fontoura, Luiza 21 March 2017 (has links) The main goal of this thesis is to deposit metal particles on the surface of 2D nanoplatelets using a controlled cementation process. As a proof of concept, copper (Cu) and Graphene Nanoplatelets (GNP) were chosen as the representative metal and 2D nanoplatelets, respectively. Specific goals of this study include depositing nanometer scale Cu particles on the surface of GNP at a low concentration (approximately 5 vol.%) while maintaining clustering and impurities at a minimum. Parametric studies were done to attain these goals by investigating various metallic reducer types and morphologies, GNP surface activation process, acid volume % and copper (II) sulfate concentrations. Optimal conditions were obtained with Mg ribbon as a reducer, 3 minutes of activation, 1 vol.% of acetic acid and 0.01 M CuSO4. The GNP-Cu powder synthesized in this work is a precursor material to be consolidated via spark plasma sintering (SPS) to make a nacre-like, layered structure for future studies. graphene nanoplatelets 2D materials cementation process single displacement reaction parametric study copper nanoparticles spark plasma sintering nacre Other Materials Science and Engineering
109	Modeling Thermochemical Nonequilibrium Processes and Flow Field Simulations of Spark-Induced Plasma Julien Keith Louis Brillon (8292123) 24 April 2020 (has links) This study is comprised of two separate parts: (1) modeling thermochemical nonequilibrium processes, and (2) flow field simulations of spark-induced plasma. In the first part, the methodology and literature for modeling thermochemical nonequilibrium processes in partially ionized air is presented and implemented in a zero-dimensional solver, termed as NEQZD. The solver was verified for a purely reacting flow case as well as two thermochemical nonequilibrium flow cases. A three-temperature electron-electronic model for thermochemical nonequilibrium partially ionizing air mixture was implemented and demonstrated the ability to capture additional physics compared to the legacy two-temperature model through the inclusion of electronic energy nonequilibrium. In the second part of this work, full scale axisymmetric simulations of the flow field produced by the abrupt heat release of spark-induced plasma were presented and analyzed for two electrode configurations. The heat release was modeled based on data from experiments and assumed that all electrical power supplied to the electrodes is converted to thermal energy. It was found that steeper electrode walls lead to a greater region of hot gas, a stronger shock front, and slightly larger vortices. Aerospace Engineering nonequilibrium hypersonic flow three-temperature model 11 species model NEQZD zero-dimensional simulations spark plasma NRP discharges
110	Processing and Characterization of Nickel-Carbon Base Metal Matrix Composites Borkar, Tushar Murlidhar 05 1900 (has links) Carbon nanotubes (CNTs) and graphene nanoplatelets (GNPs) are attractive reinforcements for lightweight and high strength metal matrix composites due to their excellent mechanical and physical properties. The present work is an attempt towards investigating the effect of CNT and GNP reinforcements on the mechanical properties of nickel matrix composites. The CNT/Ni (dry milled) nanocomposites exhibiting a tensile yield strength of 350 MPa (about two times that of SPS processed monolithic nickel ~ 160 MPa) and an elongation to failure ~ 30%. In contrast, CNT/Ni (molecular level mixed) exhibited substantially higher tensile yield strength (~ 690 MPa) but limited ductility with an elongation to failure ~ 8%. The Ni-1vol%GNP (dry milled) nanocomposite exhibited the best balance of properties in terms of strength and ductility. The enhancement in the tensile strength (i.e. 370 MPa) and substantial ductility (~40%) of Ni-1vol%GNP nanocomposites was achieved due to the combined effects of grain refinement, homogeneous dispersion of GNPs in the nickel matrix, and well-bonded Ni-GNP interface, which effectively transfers stress across metal-GNP interface during tensile deformation. A second emphasis of this work was on the detailed 3D microstructural characterization of a new class of Ni-Ti-C based metal matrix composites, developed using the laser engineered net shaping (LENSTM) process. These composites consist of an in situ formed and homogeneously distributed titanium carbide (TiC) as well as graphite phase reinforcing the nickel matrix. 3D microstructure helps in determining true morphology and spatial distribution of TiC and graphite phase as well as the phase evolution sequence. These Ni-TiC-C composites exhibit excellent tribological properties (low COF), while maintaining a relatively high hardness. Spark plasma sintering SPS laser engineering net shaping LENSTM nickel carbon nanotube CNT grapheme nanoplatelet GNP titanium carbide TiC phase evolution Nickel. Carbon nanotubes. Graphene. Metallic composites.

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