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1	Synthesis, characterization and barrier properties of sulfone-containing polymers Zhang, Tianhong January 1994 (has links) No description available. Chemistry, Polymer
2	Caracterização do comportamento geotécnico do EPS através de ensaios mecânicos e hidráulicos / Characterization of geotechnical behavior of EPS through mechanical and hydraulic tests Avesani Neto, José Orlando 28 March 2008 (has links) O poliestireno expandido (EPS), conhecido popularmente no Brasil como Isopor®, foi introduzido recentemente no país como material de baixa massa específica para construções de aterros, principalmente sobre solos moles, e encontro de pontes. Contudo, ainda não há experiência consolidada deste material em ensaios do ponto de vista da engenharia geotécnica entre nós. Este trabalho apresenta os resultados da primeira pesquisa com ensaios mecânicos e hidráulicos de laboratório específicos da caracterização do EPS para o uso geotécnico. Os ensaios mecânicos compreenderam compressão uniaxial simples e cíclica, compressão triaxial, cisalhamento direto e de interface (junta) e fluência em compressão. Os ensaios hidráulicos incluíram absorção de água por imersão e permeabilidade. Um ensaio de perda de massa por ataque de roedores foi realizado de forma simples, e ensaios químicos foram feitos para estudar o polímero. As amostras ensaiadas foram escolhidas de modo a se abranger ao máximo àquelas utilizadas em obras. Tentou-se, também, antecipar a utilização de amostras não convencionais, com massas específicas elevadas e de materiais reciclados. Os resultados mostram que o EPS possui uma grande resistência a solicitações de compressão simples, cíclica e triaxial, de cisalhamento, elevado valor de ângulo de atrito da junta e absorção de água, permeabilidade variável com a massa específica e baixo coeficiente de Poisson. Estas propriedades chave, aliado ao baixo peso específico oferecem a este material um grande potencial de aplicação como geossintético na engenharia geotécnica. / Expanded polystyrene (EPS), in Brazil, commonly know as Isopor®, has been recently introduced in this country as lightweight material for construction of embankments on soft soils, and bridge abutments. Despite this fact, there is no consolidated experience, in Brazil, in testing this product from a geotechnical point of view. This paper presents the first research data, obtained in Brazil, on mechanical and hydraulic laboratory tests, aiming the characterization of EPS samples specifically for geotechnical use. The mechanical tests comprised simple and cyclic unconfined compression, triaxial compression, joint and direct shear and creep in compression. The hydraulic tests included water absorption by immersion and water permeability. A simple loss weight test by mice attack was also conducted. And chemical tests were done to study the polymer. The results show that EPS has a great resistance to simple, cyclic and triaxial compression and joint shear solicitation, high friction angle and water absorption, varied permeability with the density and low Poisson coefficient. These key properties with its very low density give this material large potential application for geosynthetic use in geotechnical engineering. Caracterização e propriedades Characterization and properties Ensaios de laboratório Expanded polystyrene (EPS) Geoexpandido Geofoam Geofoam Geossintéticos Geosynthetics Laboratory tests Poliestireno expandido (EPS)
3	Caracterização do comportamento geotécnico do EPS através de ensaios mecânicos e hidráulicos / Characterization of geotechnical behavior of EPS through mechanical and hydraulic tests José Orlando Avesani Neto 28 March 2008 (has links) O poliestireno expandido (EPS), conhecido popularmente no Brasil como Isopor®, foi introduzido recentemente no país como material de baixa massa específica para construções de aterros, principalmente sobre solos moles, e encontro de pontes. Contudo, ainda não há experiência consolidada deste material em ensaios do ponto de vista da engenharia geotécnica entre nós. Este trabalho apresenta os resultados da primeira pesquisa com ensaios mecânicos e hidráulicos de laboratório específicos da caracterização do EPS para o uso geotécnico. Os ensaios mecânicos compreenderam compressão uniaxial simples e cíclica, compressão triaxial, cisalhamento direto e de interface (junta) e fluência em compressão. Os ensaios hidráulicos incluíram absorção de água por imersão e permeabilidade. Um ensaio de perda de massa por ataque de roedores foi realizado de forma simples, e ensaios químicos foram feitos para estudar o polímero. As amostras ensaiadas foram escolhidas de modo a se abranger ao máximo àquelas utilizadas em obras. Tentou-se, também, antecipar a utilização de amostras não convencionais, com massas específicas elevadas e de materiais reciclados. Os resultados mostram que o EPS possui uma grande resistência a solicitações de compressão simples, cíclica e triaxial, de cisalhamento, elevado valor de ângulo de atrito da junta e absorção de água, permeabilidade variável com a massa específica e baixo coeficiente de Poisson. Estas propriedades chave, aliado ao baixo peso específico oferecem a este material um grande potencial de aplicação como geossintético na engenharia geotécnica. / Expanded polystyrene (EPS), in Brazil, commonly know as Isopor®, has been recently introduced in this country as lightweight material for construction of embankments on soft soils, and bridge abutments. Despite this fact, there is no consolidated experience, in Brazil, in testing this product from a geotechnical point of view. This paper presents the first research data, obtained in Brazil, on mechanical and hydraulic laboratory tests, aiming the characterization of EPS samples specifically for geotechnical use. The mechanical tests comprised simple and cyclic unconfined compression, triaxial compression, joint and direct shear and creep in compression. The hydraulic tests included water absorption by immersion and water permeability. A simple loss weight test by mice attack was also conducted. And chemical tests were done to study the polymer. The results show that EPS has a great resistance to simple, cyclic and triaxial compression and joint shear solicitation, high friction angle and water absorption, varied permeability with the density and low Poisson coefficient. These key properties with its very low density give this material large potential application for geosynthetic use in geotechnical engineering. Caracterização e propriedades Ensaios de laboratório Geoexpandido Geofoam Geossintéticos Poliestireno expandido (EPS) Characterization and properties Expanded polystyrene (EPS) Geofoam Geosynthetics Laboratory tests
4	Process Characterization Of Composite Structures Manufactured Using Resin Impregnation Techniques Miskbay, Onur Adem 01 February 2009 (has links) (PDF) The aim of this study is to investigate and compare the properties of two layer carbon epoxy composite plates manufactured using various resin impregnation techniques / Resin Transfer Molding (RTM), Light RTM (LRTM), Vacuum Assisted RTM (VARTM) and Vacuum Packaging (VP). Throughout the study a different packaging method was developed and named Modified Vacuum Packaging (BP). The mechanical properties of composite plates manufactured are examined by tensile tests, compressive tests, in-plane shear tests and their thermal properties are examined by Differential Scanning Calorimetry (DSC) and Thermo Gravimetric Analysis (TGA) tests. All tests were performed according to suitable ASTM standards. The performance of specimens from each process was observed to vary according to the investigated property / however the VP process showed the highest performance for most properties. For most of the tests, VARTM, LRTM and RTM methods were following VP process in terms of performance, having close results with each other. TJ Mechanical Engineering. 1-1570
5	Karakterizacija kompozitnih nosioca flekso štamparskih formi i njihov uticaj na kvalitet štampe kartonske ambalaže / Characterization of composite flexographic printing plate carriers and theirinfluence on cardboard packaging print quality Petrović Saša 11 December 2020 (has links) <p>U disertaciji je izvršena karakterizacija sliv nosioca flekso<br />štamparskih formi i predstavljena su istraživanja uticaja promene<br />mehaničkih i adhezivnih svojstava slivova na parametre kvaliteta<br />štampe kartonske ambalaže. Korišćene su dve grupe samolepljivih<br />slivova (potpuno novi i slivovi korišćeni za štampu 5.000.000 m<br />materijala). Ciljevi istraživanja su povećanje predvidivosti i<br />konstantnosti kvaliteta štampanog proizvoda i procesa proizvodnje<br />kartonske ambalaže, formiranje preporuka za upotrebu slivova<br />različitih svojstava i nivoa eksploatisanosti i otkrivanje u kojim<br />fazama i kojim procesima dolazi do promena svojstava slivova.</p> / <p>Research presented in this dissertation includes characterization of<br />flexographic sleeves and the study of the influence of the changes in<br />mechanical and adhesive properties of the sleeves on print quality<br />parameters of the cardboard packaging. Two groups of self-adhesive sleeves<br />were used (entirely new and sleeves used for printing of 5.000.000 m of<br />material). Aims of the research are the increase in predictability and stability<br />of the printed product quality and the production process of cardboard<br />packaging, forming of the recommendations for the use of sleeves with<br />different properties and levels of exploitation, as well as defining the phases<br />and processes responsible for the changes in sleeve properties.</p>
6	Correlating Photoconductivity with Photochromism in Oxygen-containing Rare-earth Metal Hydride Thin Films Kazi, Suraya January 2021 (has links) Scientists have recently discovered simultaneous photoconductivity and photochromism (i.e., optical switching upon light exposure) of oxygen-containing rare-earth metal hydrides (REMHO). A deep understanding of these extraordinary optical and electrical properties can open the door to advanced technological uses such as smart windows. This thesis work is to establish a correlation between the photochromism of these materials with their photoconductive response and comprehend the underlying physics behind them. The samples were grown by reactive magnetron sputtering. The dynamics of the photochromic effect were observed by recording the time-resolved relative transmittance of the films during photodarkening and bleaching using a UV-vis spectrometer. The samples were characterized electrically by employing the two-point probe resistance measurement. The depth profiles of the concentration of chemical elements were extracted from Ion Beam Analysis. A systematic study was performed to see how the photoconductive and photochromic responses of the REMHO thin films depend on the wavelength and intensity of the illuminating light as well as the chemical composition of the films. Both effects showed i) higher response for shorter wavelength, ii) a cut-off near a similar wavelength, iii) saturation near UV region, and iv) similar relaxation time but with different kinetics. Multiple measurements performed on the same sample showed that the previous measurement affects the next measurement indicating a memory effect. Finally, the photoconductive response showed an increase with increasing oxygen concentration. Condensed Matter Physics Den kondenserade materiens fysik
7	Crystal Growth, Structure and Anisotropic Magnetic Properties of Quasi-2D Materials Selter, Sebastian 15 June 2021 (has links) In this work, the crystal growth as well as structural and magnetic investigations of several metal trichalcogenides compounds with a general formula M2X2Ch6 are presented. M stands for a main group metal or transition metal, X is an element of the IV or V main group and Ch is a chalcogen. In particular, these compounds are the phosphorus sulfides Fe2P2S6, Ni2P2S6 as well as intermediate compounds of the substitution regime (Fe1-xNix)2P2S6, the quarternary phosphorus sulfides CuCrP2S6 and AgCrP2S6 and the germanium tellurides Cr2Ge2Te6 and In2Ge2Te6. As members of the metal trichalcogenides, all these compounds have a van der Waals layered honeycomb structure in common. This layered structure in combination with their magnetic properties makes these compounds interesting candidate materials for the production of magnetic monolayers by exfoliation from bulk crystals. Crystals of the phosphorus sulfides were grown by the chemical vapor transport technique and, for the growth of the germanium tellurides, the self-flux growth technique was used. Crystals of all phases were extensively characterized regarding their morphology, chemical composition and homogeneity as well as regarding their crystal structure. The structural analysis, especially for Ni2P2S6, yields insight into details of the stacking order and disorder of the corresponding quasi-two-dimensional layers in the bulk. Regarding the magnetic properties, both Fe2P2S6 and Ni2P2S6 order antiferromagnetically but exhibit different magnetic anisotropies (i.e. Ising-like anisotropy for Fe2P2S6 and XYZ anisotropy for Ni2P2S6). In this context, it is surprising to find that compounds in the solid solution regime of (Fe1-xNix)2P2S6 up to x = 0.9 exhibit an anisotropic magnetic behavior that is comparable to Fe2P2S6 and, thus, indicative of Ising-like anisotropy. For CuCrP2S6 and AgCrP2S6, the ordering of the two different transition elements on the honeycomb sites yields more complex magnetic structures. The magnetic Cr3+ atoms in CuCrP2S6 order in a triangular arrangement and form an antiferromagnetic ground state with notable ferromagnetic interactions. AgCrP2S6 exhibits pronounced features of low dimensional magnetism resulting from the (quasi-)one-dimensional stripe-like arrangement of magnetic Cr3+ atoms and no onset of long-range magnetic order is unambiguously observed. Cr2Ge2Te6 exhibits ferromagnetic order and an anisotropic feature in the temperature dependence of the magnetization. Based on the magnetic phase diagrams for two orientations between the magnetic field and the crystallographic directions, the temperature dependence of the magnetocrystalline anisotropy constant as well as the critical exponents of the magnetic phase transition are extracted. Concluding from this, the magnetic interactions in Cr2Ge2Te6 are dominantly of two-dimensional nature and the anisotropy is uniaxial with the before mentioned anisotropic feature resulting from the interplay between magnetocrystalline anisotropy, magnetic field, and temperature. In2Ge2Te6 is diamagnetic as to be expected for a closed-shell system. Additional to the investigations on single crystals, the quasi-binary phase diagram of (Cu1-xAgx)CrP2S6 was investigated for regimes of solid solution behavior based on polycrystalline samples. Accordingly, isostructural substitution is most likely possible in the composition range of (Cu0.25Ag0.75)CrP2S6 to AgCrP2S6, potentially allowing to tune the magnetic interactions of the Cr sublattice indirectly by substitution on the Cu/Ag sublattice.:1. Introduction 1.1. M2X2Ch6 Class of Materials 1.2. Magnetism in Solid State Materials 1.2.1. Diamagnetism 1.2.2. Paramagnetism 1.2.3. Cooperative Magnetism 1.2.4. Magnetic Anisotropy 1.2.5. Magnetism in D < 3 1.2.6. Critical Exponents 2. Methods 2.1. Synthesis and Crystal Growth 2.1.1. Solid State Synthesis 2.1.2. Crystal Growth via the Liquid Phase 2.1.3. Crystal Growth via the Vapor Phase 2.2. X-ray Diffraction 2.2.1. Single Crystal X-ray Diffraction 2.2.2. Powder X-ray Diffraction 2.3. Scanning Electron Microscopy and Energy Dispersive X-ray Spectroscopy 2.3.1. Scanning Electron Microscopy 2.3.2. Energy Dispersive X-ray Spectroscopy 2.4. Magnetometry 2.5. Nuclear Magnetic Resonance Spectroscopy 2.6. Specific Heat Capacity 3. M2P2S6 3.1. Ni2P2S6 3.1.1. Crystal Growth 3.1.2. Characterization 3.1.3. Magnetic Properties 3.1.4. 31P-NMR Spectroscopy 3.1.5. Stacking (Dis-)Order in Ni2P2S6 3.2. (Fe1-xNix)2P2S6 3.2.1. Synthesis and Crystal Growth 3.2.2. Characterization 3.2.3. Evolution of Magnetic Properties 3.3. Summary and Outlook 4. M1+CrP2S6 4.1. CuCrP2S6 4.1.1. Crystal Growth 4.1.2. Characterization 4.1.3. Magnetic Properties 4.2. AgCrP2S6 4.2.1. Crystal Growth 4.2.2. Characterization 4.2.3. Magnetic Properties 4.3. Polycrystalline (Cu1-xAgx)CrP2S6 4.3.1. Synthesis 4.3.2. Phase Analysis 4.4. Summary and Outlook 5. M2(Ge,Si)2Te6 5.1. Cr2Ge2Te6 5.1.1. Crystal Growth 5.1.2. Characterization 5.1.3. Magnetic Properties 5.1.4. Analysis of the Critical Behavior 5.2. In2Ge2Te6 5.2.1. Crystal Growth 5.2.2. Characterization 5.2.3. Magnetic Properties 5.2.4. Specific Heat 5.3. Summary and Outlook 6. Conclusion Bibliography List of Publications Acknowledgements Eidesstattliche Erklärung A. Appendix A.1. Scanning Electron Microscopic Images A.1.1. (Fe1-xNix)2P2S6 A.2. scXRD A.2.1. (Fe1-xNix)2P2S6 / In dieser Arbeit werden die Kristallzüchtung sowie strukturelle und magnetische Untersuchungen an mehreren Metalltrichalkogenid-Verbindungen mit der allgemeinen Summenformel M2X2Ch6 vorgestellt. M steht für ein Hauptgruppen- oder Übergangsmetall, X ist ein Element der IV- oder V-Hauptgruppe und Ch ein Chalkogen. Insbesondere handelt es sich bei diesen Verbindungen um die Phosphorsulfide Fe2P2S6, Ni2P2S6 sowie um Verbindungen der Substitutionsreihe (Fe1-xNix)2P2S6, die quaternären Phosphorsulfide CuCrP2S6 und AgCrP2S6 sowie die Germaniumtelluride Cr2Ge2Te6 und In2Ge2Te6. Als Mitglieder der Metalltrichalkogenide haben alle diese Verbindungen eine van-der-Waals-Schichtstruktur mit Honigwabenmotiv gemein. Diese Schichtstruktur in Kombination mit ihren magnetischen Eigenschaften macht diese Verbindungen zu interessanten Kandidaten für die Herstellung von magnetischen Monolagen durch Exfoliation aus Volumenkristallen. Kristalle der Phosphorsulfide wurden mit der chemischen Dampfphasentransporttechnik gezüchtet und für die Züchtung der Germaniumtelluride wurde die Selbstflusstechnik verwendet. Die Kristalle aller Phasen wurden sowohl hinsichtlich ihrer Morphologie, chemischen Zusammensetzung und Homogenität als auch hinsichtlich ihrer Kristallstruktur umfassend charakterisiert. Die Strukturanalyse, insbesondere für Ni2P2S6, gibt Aufschluss über Details der Stapelordnung und -unordnung der entsprechenden quasizweidimensionalen Schichten im Volumen. Bezüglich der magnetischen Eigenschaften ordnen sowohl Fe2P2S6 als auch Ni2P2S6 antiferromagnetisch, zeigen aber unterschiedliche magnetische Anisotropien (d.h. Ising-artige Anisotropie für Fe2P2S6 und XYZ-Anisotropie für Ni2P2S6). In diesem Zusammenhang ist es überraschend, dass Verbindungen im Mischkristallregime von (Fe1-xNix)2P2S6 bis x = 0.9 ein anisotropes magnetisches Verhalten zeigen, das mit dem von Fe2P2S6 vergleichbar ist und daher auf Ising-artige Anisotropie hindeutet. Bei CuCrP2S6 und AgCrP2S6 führt die Anordnung der beiden unterschiedlichen Übergangselemente auf den Gitterplätzen der Wabenstruktur zu komplexeren magnetischen Strukturen. Die magnetischen Cr3+ Atome in CuCrP2S6 ordnen sich in einer Dreiecksanordnung an und bilden einen antiferromagnetischen Grundzustand mit ausgeprägten ferromagnetischen Wechselwirkungen. AgCrP2S6 weist deutliche Merkmale von niederdimensionalem Magnetismus auf, welche aus der (quasi-)eindimensionalen, streifenartigen Anordnung der magnetischen Cr3+ Atome resultieren, und das Einsetzen von langreichweitiger magnetischer Ordnung kann nicht eindeutig beobachtet werden. Cr2Ge2Te6 weist ferromagnetische Ordnung und einen anisotropen Verlauf der Temperaturabhängigkeit der Magnetisierung auf. Anhand von magnetischen Phasendiagrammen für zwei Orientierungen zwischen Magnetfeld und kristallographischen Richtungen wurden die Temperaturabhängigkeit der magnetokristallinen Anisotropiekonstante sowie die kritischen Exponenten des magnetischen Phasenübergangs extrahiert. Hieraus ergibt sich, dass die magnetischen Wechselwirkungen in Cr2Ge2Te6 überwiegend zweidimensionaler Natur sind und die Anisotropie uniaxial ist, wobei der zuvor erwähnte anisotrope Verlauf aus dem Zusammenspiel von magnetokristalliner Anisotropie, Magnetfeld und Temperatur resultiert. In2Ge2Te6 ist diamagnetisch, wie es für ein System mit geschlossener Schale zu erwarten ist. Zusätzlich zu den Untersuchungen an Einkristallen wurde das quasibinäre Phasendiagramm von (Cu1-xAgx)CrP2S6 anhand von polykristallinen Proben auf Bereiche mit Mischkristallverhalten hin untersucht. Folglich ist eine isostrukturelle Substitution höchstwahrscheinlich im Zusammensetzungsbereich von (Cu0.25Ag0.75)CrP2S6 bis AgCrP2S6 möglich, was es erlauben könnte, die magnetischen Wechselwirkungen des Cr-Untergitters indirekt durch Substitution auf dem Cu/Ag-Untergitter zu beeinflussen.:1. Introduction 1.1. M2X2Ch6 Class of Materials 1.2. Magnetism in Solid State Materials 1.2.1. Diamagnetism 1.2.2. Paramagnetism 1.2.3. Cooperative Magnetism 1.2.4. Magnetic Anisotropy 1.2.5. Magnetism in D < 3 1.2.6. Critical Exponents 2. Methods 2.1. Synthesis and Crystal Growth 2.1.1. Solid State Synthesis 2.1.2. Crystal Growth via the Liquid Phase 2.1.3. Crystal Growth via the Vapor Phase 2.2. X-ray Diffraction 2.2.1. Single Crystal X-ray Diffraction 2.2.2. Powder X-ray Diffraction 2.3. Scanning Electron Microscopy and Energy Dispersive X-ray Spectroscopy 2.3.1. Scanning Electron Microscopy 2.3.2. Energy Dispersive X-ray Spectroscopy 2.4. Magnetometry 2.5. Nuclear Magnetic Resonance Spectroscopy 2.6. Specific Heat Capacity 3. M2P2S6 3.1. Ni2P2S6 3.1.1. Crystal Growth 3.1.2. Characterization 3.1.3. Magnetic Properties 3.1.4. 31P-NMR Spectroscopy 3.1.5. Stacking (Dis-)Order in Ni2P2S6 3.2. (Fe1-xNix)2P2S6 3.2.1. Synthesis and Crystal Growth 3.2.2. Characterization 3.2.3. Evolution of Magnetic Properties 3.3. Summary and Outlook 4. M1+CrP2S6 4.1. CuCrP2S6 4.1.1. Crystal Growth 4.1.2. Characterization 4.1.3. Magnetic Properties 4.2. AgCrP2S6 4.2.1. Crystal Growth 4.2.2. Characterization 4.2.3. Magnetic Properties 4.3. Polycrystalline (Cu1-xAgx)CrP2S6 4.3.1. Synthesis 4.3.2. Phase Analysis 4.4. Summary and Outlook 5. M2(Ge,Si)2Te6 5.1. Cr2Ge2Te6 5.1.1. Crystal Growth 5.1.2. Characterization 5.1.3. Magnetic Properties 5.1.4. Analysis of the Critical Behavior 5.2. In2Ge2Te6 5.2.1. Crystal Growth 5.2.2. Characterization 5.2.3. Magnetic Properties 5.2.4. Specific Heat 5.3. Summary and Outlook 6. Conclusion Bibliography List of Publications Acknowledgements Eidesstattliche Erklärung A. Appendix A.1. Scanning Electron Microscopic Images A.1.1. (Fe1-xNix)2P2S6 A.2. scXRD A.2.1. (Fe1-xNix)2P2S6 info:eu-repo/classification/ddc/530 ddc:530

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