Global ETD Search

101	EFFECTS OF SOLUTION COMPOSITION (SALTS, PH, DIELECTRIC CONSTANT) ON POLYELECTROLYTE COMPLEX (PEC) FORMATION AND THEIR PROPERTIES ZHANG, HUAN January 2018 (has links) No description available. Polymers Materials Science
102	CARBON NANOTUBE REINFORCED DYNAMIC MATERIALS SYNTHESIZED BY REVERSIBLE ADDITION FRAGMENTATION CHAIN TRANSFER (RAFT) POLYMERIZATION Stopler, Erika Brooke 02 August 2019 (has links) No description available. Materials Science Chemistry Polymer Chemistry Polymers RAFT polymers Diels-Alder dynamic materials self-healing carbon nanotubes materials
103	Development of Methods to Validate the Effectiveness of Self-Healing Concrete and Microbial Nutrients Dahal, Puskar Kumar 04 December 2022 (has links) No description available. Civil Engineering Engineering Materials Science
104	Advanced Theory, Materials and Applications for Electrowetting on Structured Surfaces Dhindsa, Manjeet S. 19 April 2011 (has links) No description available. Electrical Engineering Electrowetting on structured surfaces Parylene HT Reliable electrowetting Virtual electrowetting channels
105	UNDERSTANDING AND IMPROVING LITHIUM ION BATTERIES THROUGH MATHEMATICAL MODELING AND EXPERIMENTS Deshpande, Rutooj D. 01 January 2011 (has links) There is an intense, worldwide effort to develop durable lithium ion batteries with high energy and power densities for a wide range of applications, including electric and hybrid electric vehicles. For improvement of battery technology understanding the capacity fading mechanism in batteries is of utmost importance. Novel electrode material and improved electrode designs are needed for high energy- high power batteries with less capacity fading. Furthermore, for applications such as automotive applications, precise cycle-life prediction of batteries is necessary. One of the critical challenges in advancing lithium ion battery technologies is fracture and decrepitation of the electrodes as a result of lithium diffusion during charging and discharging operations. When lithium is inserted in either the positive or negative electrode, there is a volume change associated with insertion or de-insertion. Diffusion-induced stresses (DISs) can therefore cause the nucleation and growth of cracks, leading to mechanical degradation of the batteries. With different mathematical models we studied the behavior of diffusion induces stresses and effects of electrode shape, size, concentration dependent material properties, pre-existing cracks, phase transformations, operating conditions etc. on the diffusion induced stresses. Thus we develop tools to guide the design of the electrode material with better mechanical stability for durable batteries. Along with mechanical degradation, chemical degradation of batteries also plays an important role in deciding battery cycle life. The instability of commonly employed electrolytes results in solid electrolyte interphase (SEI) formation. Although SEI formation contributes to irreversible capacity loss, the SEI layer is necessary, as it passivates the electrode-electrolyte interface from further solvent decomposition. SEI layer and diffusion induced stresses are inter-dependent and affect each-other. We study coupled chemical-mechanical degradation of electrode materials to understand the capacity fading of the battery with cycling. With the understanding of chemical and mechanical degradation, we develop a simple phenomenological model to predict battery life. On the experimental part we come up with a novel concept of using liquid metal alloy as a self-healing battery electrode. We develop a method to prepare thin film liquid gallium electrode on a conductive substrate. This enabled us to perform a series of electrochemical and characterization experiments which certify that liquid electrode undergo liquid-solid-liquid transition and thus self-heals the cracks formed during de-insertion. Thus the mechanical degradation can be avoided. We also perform ab-initio calculations to understand the equilibrium potential of various lithium-gallium phases. Lithium ion batteries diffusion induced stresses self-healing electrode life-prediction model Chemical Engineering Engineering Materials Science and Engineering
106	Fabricação e caracterização de filme fino regenerável hidrofóbico / Fabrication and characterization of healable hydrophobic thin film Ly, Kally Chein Sheng, 1992- 28 August 2017 (has links) Orientador: Antonio Riul Júnior / Dissertação (mestrado) - Universidade Estadual de Campinas, Instituto de Física Gleb Wataghin / Made available in DSpace on 2018-09-02T14:50:41Z (GMT). No. of bitstreams: 1 Ly_KallyCheinSheng_M.pdf: 2442128 bytes, checksum: 86716c6c19fa3a9db425b32c36463141 (MD5) Previous issue date: 2017 / Resumo: Materiais biomiméticos são inspirados em estruturas biológicas para a obtenção de propriedades e funcionalidades específicas. Dentre os materiais biomiméticos, os que são capazes de se regenerar (self-healing) despertaram grande interesse pelo potencial de aplicação em diversas áreas. Para ilustrar, alguns materiais autorregeneráveis poliméricos apresentam regeneração múltipla, necessitando apenas de água para que a regeneração ocorra em alguns minutos, aumentando consideravelmente a proteção mecânica da superfície contra desgastes, danos mecânicos entre outros. Entretanto, múltiplas imersões em água ou em meios aquosos pode degradar o material e neste contexto este projeto visa incorporar a hidrofobicidade a um sistema regenerável. Desta forma, o material regenerável hidrofóbico, durante sua regeneração imersa em água, poderá diminuir a interação da superfície não danificada com a água, reduzindo corrosões e degradações devido a meios aquosos. Estudamos a nanoestruturação de materiais através da técnica de automontagem por adsorção física (LbL, do inglês Layer-by-Layer) utilizando os polieletrólitos poli(etileno imina) (PEI) e poli(ácido acrílico) (PAA), a fim de produzir revestimentos capazes de se regenerar a danos mecânicos micrométricos. Adicionalmente, foram incorporados a estes dois materiais nanofolhas de óxido de grafeno reduzido (rGO) funcionalizados com poli(cloridrato de alilamina) (GPAH) e poli(estireno-sulfonato de sódio) (GPSS), com o intuito de verificarmos um aumento de resistência a abrasão do material e alterações nas propriedades elétricas na nanoestrutura formada para aumentar o potencial de aplicação em eletrônica flexível. A arquitetura molecular (GPAH-PEI/GPSS-PAA)60 foi caracterizada com espectroscopia Raman, medidas de ângulo de contato, microscopia de força atômica, medidas elétricas e nanoindentação. Foi observada boa regeneração do material após 15 minutos de imersão em água a temperatura ambiente em um dano mecânico da ordem de 10 micrômetros. Também observamos boa hidrofobicidade do filme LbL (GPAH-PEI/GPSS-PAA)60 ( teta = 136º), e medidas de microscopia de força atômica e perfilometria indicaram, respectivamente, rugosidade superficial de 55 nm em uma área de (2 ?m x 2 ?m) e espessura de filme de 30 ?m. A análise Raman apontou para uma forte interação das nanofolhas de rGO com os polímeros, corroborando o tem caráter elétrico isolante do filme (GPAH-PEI/GPSS-PAA)60, que apresentou função trabalho ~ 5,2 eV e condutividade elétrica da ordem de 10-7 S/cm, que acreditamos resultar das fortes interações das nanofolhas com os polímeros. Por fim, medidas de nanoindentação indicaram que a incorporação de nanofolhas de GPSS e GPAH aumentou em 10 vezes a dureza do nanocompósito formado, sem comprometer a regeneração / Abstract: Biomimetic materials are inspired in biological structures to obtain specific properties and functionalities and among them, those capable of self-healing brought great interest due to high potential of application in different areas. To illustrate, some polymeric self-healing materials present multiple regeneration in the presence of water, with the regeneration occurring within a few minutes, increasing considerably the mechanical protection of a surface against wear and mechanical damage among others. Nevertheless, multiple immersions in water or in aqueous media can degrade the material and in this context this project aims the incorporation of hydrophobicity to a self-healing system. In this way, the self-healing, hydrophobic material during its immersion in water may decrease the interaction of the damaged surface with water, reducing corrosion and degradation due to aqueous media. We study the nanostructuration f materials through the layer-by-layer (LbL) technique using poly(ethylene imine) (PEI) and poly(acrylic acid) (PAA) in order to produce self-healing coatings from micrometric mechanical damages. In addition, we also incorporate to these materials reduced graphene oxide (rGO) functionalized with poly(allylamine hydrochloride) (GPAH) and poly(styrene-sodium sulfonate) (GPSS), with the purpose of verifying an increase in the mechanical abrasion resistance of the material and changes in the electrical properties of the nanostructures formed to increase the potential application in flexible electronics. The molecular architecture (GPAH-PEI/GPSS-PAA)60 was characterized by Raman spectroscopy, contact angle measurements, atomic force microscopy, electrical measurements and nanoindentation. It was observed good self-healing capacity after 15 min f immersion in water at room temperature in a mechanical scratch of the order of 10 micrometers. It was also observed good hydrophobicity in the (GPAH-PEI/GPSS-PAA)60 LbL film ( teta = 136º) and atomic force microscopy and perfilometer indicate, respectively, surface roughness of 55 nm in a (2 ?m x 2 ?m) area and film thickness of 30 ?m. Raman analysis pointed out to a strong physical interaction between the rGO nanoplatelets with the polymeric materials, corroborating the strong insulating nature of (GPAH-PEI/GPSS-PAA)60 film that displayed a work function of 5.2 eV and electrical conductivity of 10-7 S/cm, which we believe results from the strong interactions of the nanosheets with the polymers. Finally, nanoindentation measurements indicated that the incorporation of GPAH and GPSS nanoplatelets increased hardness by 10 times, without compromising the regeneration / Mestrado / Física / Mestra em Física / 1543078/2015 / CAPES Materiais inteligentes Materiais nanocompósitos poliméricos Materiais de autocuração Óxido de grafeno reduzido Filmes finos Hidrofobicidade Smart materials Polymeric nanocomposite materials Self-healing materials Reduced graphene oxide Thin films Hydrophobicity
107	Silicone supramoléculaire : un nouveau concept permettant l'auto-cicatrisation / Supramolecular silicone : a new concept allowing self-healing Simonin, Léo 03 December 2018 (has links) Les silicones auto-cicatrisants de façon autonome (sans stimulus externe) présentent de faibles propriétés mécaniques, limitant leur utilisation industrielle. L’objectif de cette étude était de dépasser cette limitation. Nos travaux se sont intéressés aux copolymères segmentés PDMS-urée constitués de blocs souples (SS) et rigides (HS). Tout d’abord, nous avons étudié la relation entre la structure des bis-urées et les propriétés macroscopiques. Nous avons ainsi montré que la symétrie des HS gouverne la rigidité de ces matériaux. Toutefois, la présence de HS symétriques inhibe la cicatrisation du matériau. Puis, nous avons développé un nouveau concept permettant d’accélérer leur cinétique de cicatrisation. Un stoppeur de chaine macromoléculaire a été ajouté à la formulation de ces silicones thermoplastiques, créant un défaut dans l’assemblage supramoléculaire, conduisant à des clusters organiques plus petits et plus dynamiques. Néanmoins, contrairement aux plastifiants, la chute du module de Young observée par rapport à la matrice est limitée. D’ailleurs, nous reportons la synthèse d’un copolymère PDMS-urée avec un module de traction de 1MPa dont 90% de la contrainte à rupture peut être récupérée après cicatrisation pendant 24h à 25°C. Ce concept a aussi été adapté à un thermoplastique commercial (GENIOMER80). Enfin, notre défi a été d’optimiser la balance entre rigidité et autocicatrisation. Dans ce contexte, nous avons synthétisé de nouvelles matrices plus rigides, ainsi que des additifs avec des groupements associatifs de plus grande énergie cohésive. Nous avons alors pu repousser la limite de rigidité accessible aux silicones auto-cicatrisants de façon autonome (3MPa). / Autonomous self-healable (without external stimulus) silicones exhibit too low mechanical properties restricting their use in industry. The aim of this study was to overcome this limitation. We focused our work on segmented PDMS-urea copolymers made of soft (SS) and hard segments (HS). First the investigation of the relationship between the bis-urea chemical structure and the macroscopic properties was made. Results shown that, the symmetry of HS governs materials rigidity. Moreover, with a too symmetrical HS, the material does not exhibit self-healing abilities. We have developed a new concept improving the healing efficiency of these materials. The idea was to add to the formulation of these silicone thermoplastics a macromolecular chain stopper. The new additive creates a defect in the supramolecular assembly which leads to smaller and more dynamic H-bonding clusters and hence a faster healing kinetic. Unlike plasticizers, this additive deteriorates the tensile modulus only marginally. We therefore report a stress at break recovery of 90% after 24 hours at room temperature for a PDMS-urea copolymer with a tensile modulus of 1MPa. The concept was also extented to a commercial thermoplastic (GENIOMER80). Finally, our last challenge was to manage the balance between rigidity and chains dynamics allowing self-healable materials with good mechanical properties. In this context we have synthesized new matrixes with higher HS percentage and additives with stickers with higher cohesive energy. These new syntheses have led to an improvement of the rigidity limit reachable by the autonomous self-healable silicones (3MPa). Silicone Autocicatrisation Liaisons hydrogène Stoppeur de chaine Bis-Urée Polymères segmentés Silicone Self-healing H-bonding Chain stopper PDMS-urea Segmented polymers 541.2254
108	Estudo da resistência à corrosão da liga de alumínio 2024-T3 clad anodizada em ácido tartárico sulfúrico e pós-tratada em banho contendo íons Ce. / Study of the corrosion resistance of 2024-T3 clad aluminum alloy analized in sulfuric tarturic acid and post-treated in a both containing Ce ions. Prada Ramirez, Oscar Mauricio 02 August 2019 (has links) Neste estudo foi avaliada a resistência à corrosão da liga 2024-T3 clad, anodizada em solução de ácido tartárico-sulfúrico (TSA) e pós-tratada em banhos contendo íons de cério (Ce(NO3)3) sem e com H2O2. O pós-tratamento visa aumentar a resistência à corrosão e conferir propriedades de auto regeneração à camada anodizada, sem, no entanto, causar o fechamento dos poros, mantendo assim as propriedades de adesão. Foram avaliados os efeitos da temperatura, do tempo de imersão e da porcentagem de H2O2 no banho de pós-tratamento sobre a microestrutura e resistência à corrosão. As observações por microscopia eletrônica de varredura (MEV) mostraram que não houve fechamento dos poros e que ocorre precipitação preferencial de oxihidróxidos de Ce nas proximidades dos defeitos da camada. A avaliação da resistência à corrosão em solução de NaCl 0,1 e 0,5 mol/L por espectroscopia de impedância eletroquímica (EIS) mostrou que a etapa de pós-tratamento em solução contendo 50 mM de Ce(NO3)3.6H2O e 10% vol. de H2O2 melhora o desempenho da camada, com o melhor resultado tendo sido obtido para a temperatura intermediária (50°C) de pós-tratamento. Os resultados dos ensaios de EIS mostraram também efeito negativo de altas temperaturas no pós-tratamento nas propriedades protetoras da camada anodizada. Esses resultados foram confirmados por fotos digitais e observação SEM das amostras após a conclusão dos experimentos de EIS. Já a caracterização composicional por meio de GDOES mostrou a incorporação de espécies de Ce dentro dos poros da camada anodizada após pós-tratamentos em solução contendo 50 mM de Ce(NO3)3.6H2O e 10% vol. H2O2 a 50°C para tempos de imersão de 2 e 5 minutos, resultados confirmados com a técnica RBS, que mostrou ainda a presença de Ce na superfície da camada e no interior dos poros mesmo após 15 dias de imersão em NaCl 0,1M. Medições de XPS mostraram que o Ce está presente na superfície das amostras nos estados de oxidação 3+ e 4+, e uma maior relação Ce3+/Ce4+ para as amostras pós-tratadas por 2 minutos. O ajuste dos diagramas de EIS com circuitos equivalentes mostrou que a selagem parcial dos poros tem papel importante na resistência à corrosão, e evidenciaram que os pós-tratamentos mais eficientes não afetam as propriedades protetoras da camada barreira. / This study evaluated the corrosion resistance of a 2024-T3 clad alloy anodized in tartaric-sulfuric acid solution (TSA) and post-treated in baths containing cerium ions, without or with H2O2. The post-treatment aims to increase the corrosion resistance and afford self-healing properties to the anodized layer, without, however, closing its porous structure, thus maintaining its adhesion properties. The effects of the temperature, immersion time and concentration of H2O2 in the post-treatment bath in the microstructure and in the corrosion resistance of the samples were evaluated. SEM observations showed that pores are not blocked and that preferential precipitation of Ce occurs in the vicinity of defective sites of the anodized layer. The evaluation of the corrosion resistance in 0.1 and 0.5 mol/L NaCl solution by means of electrochemical impedance spectroscopy (EIS) showed that the post-treatment in solutions containing 50 mM of Ce(NO3)3.6H2O and 10% vol. of H2O2 improves the corrosion resistance of the anodized samples, with the best result being obtained for the intermediary temperature (50°C) of the post-treatment bath. The results of the EIS tests also showed a negative effect of higher temperatures on the protective properties of the anodized layer. Digital photos and SEM observation of the samples after the completion of the EIS experiments confirmed these results. The compositional characterization by GDOES showed the incorporation of Ce species within the pores of the anodized layer after post-treatments in solution containing 50 mM Ce (NO3)3.6H2O and 10% vol. H2O2 at 50°C for 2 and 5 minutes, confirmed by the RBS technique, which also showed the presence of Ce both at the surface and within the pores of the layer, even after 15 days of immersion in 0.1M NaCl. XPS measurements showed the presence of Ce3+ and Ce4+ species at the post-treated samples surface and showed higher Ce3+ / Ce4+ ratio for the sample post-treated for 2 minutes. Fitting of the EIS diagrams with equivalent circuits showed that partial pore sealing plays an important role in corrosion resistance and evidenced that the most efficient post-treatments do not affect the protective properties of the barrier layer. 2024-T3 2024-T3 Anodização tartárico-sulfúrico Auto regeneração Cério Cerium Corrosão EIS EIS Ligas leves Self-healing Tartaric sulfuric anodizing
109	Corrosion protection concepts for aluminium and magnesium alloys coated with silica films prepared by water-based sol-gel process / Konzepte für den Korrosionsschutz von Aluminium-und Magnesiumlegierungen mit mittels Sol-Gel-Prozess hergestelltem Silikafilm auf Wasserbasis Darwich, Samer 14 August 2012 (has links) (PDF) The present work provides an insight in the development of silica films prepared by water-based sol-gel process. The weaknesses of the coating technology are identified, also solutions are discussed. The silica film is applied on aluminium alloy 6082-T6 and magnesium alloy AZ31. The development of the coating properties such as cost-efficiency, crack-free, self-healing and long-term corrosion protection is the main topic of this work. Cracking is the major drawback of silica films; the cracks are generated due to shrinkage of the film during the heat treatment, nanoparticles-doped silica film is successfully reduced the shrinkage which leads to crack-free silica films. The self-healing of the coated aluminium and magnesium samples is generated by corrosion inhibitors-doped silica film. When a defect appears in the film, the corrosion inhibitors leach out of the silica film to the defect area to heal the corroded surface. The long-term corrosion protection is realized by means of a mixture of corrosion inhibitors-doped silica film. / Die vorliegende Arbeit liefert einen Einblick in die Entwicklung von Silikafilmen, die mittels Sol-Gel-Prozess auf Wasserbasis hergestellt wurden. Die Schwächen der Beschichtungstechnologie werden dargestellt und Lösungen diskutiert. Der Silikafilm wird auf Aluminiumlegierung 6082-T6 und Magnesium-legierung AZ31 aufgebracht. Schwerpunkt dieser Arbeit ist die Entwicklung der Schichteigenschaften, wie Kosteneffizienz, Rissfreiheit, Selbstheilung so wie langfristiger Korrosionsschutz. Rissbildung ist ein wesentlicher Nachteil von Silikafilmen; rissfreie Filme wurden mittels nanopartikeldotierter Silikafilme hergestellt. Die Selbstheilung von Aluminium-und Magnesiumsubstraten mit Silikafilm wird durch den Effekt der wasserlöslichen Korrosionsinhibitoren generiert. Die Experimente haben gezeigt, dass die Proben mit inhibitordotierter Beschichtung selbst gegen Korrosion geschützt sind. Ein langfristiger Korrosionsschutz wird durch eine Mischung aus Korrosionsinhibitor-dotierten Silika-Film realisiert. Wasserbasis sol Silikafilm Sol-Gel-Prozess Korrosionsinhibitoren Selbstheilung Korrosionsschutz water-based sol silica film sol-gel process corrosion inhibitors self-healing corrosion protection ddc:629 Korrosionsschutz Selbstheilung
110	Applications of N-heterocycles in electrically and ionically conductive polymers Norris, Brent Carl 20 October 2011 (has links) The covalent bond formed between a N-heterocyclic carbene and an aryl-isothiocyanate was discovered to be thermally-reversible. This bond was incorporated into the backbone of an aromatic polymer which, when subjected to heat and excess monomer, would depolymerize to smaller oligomers. In addition these small molecules contain active chain ends and could be repolymerized to reform the original polymer. The high molecular weight material was made into freestanding sheets with desirable mechanical properties and could be made conductive by treatment with iodine. A new poly(triazene) was formed from the reaction of a facially opposed, annulated, bis-N-heterocyclic carbene (NHC) and an organic bis-azide. The NHC as well as the azide were varied and combined to produce a series of polymers which were characterized by GPC, TGA, and NMR. These thermally robust polymers were also coated onto glass slides and rendered electrically conductive by exposure to iodine vapor. A new reagent for Reversible Addition Fragmentation Chain Transfer Polymerization (RAFT) is described. This imidazolium based reagent shows unusually fast kinetics which allows it to control polymerizations at significantly reduced loadings compared to the more traditional neutral dithiocarbamates or dithioesters. The fast kinetics is explained by the rapid rotation of the dithioester about the plane of the cationic N-heterocycle. Sulfonated poly(ether ether ketone) (sPEEK) membranes were blended with imidazoles with varying pKas. The proton conductivity of the membranes was evaluated as a function of pKa and temperature. Interestingly, the conductivity of the dry membranes showed a non-monotonous profile over a temperature range of 25 – 150 C. We use a theoretical model to better understand the mechanistic origins of the observed temperature–conductivity profiles. This model is based on the reaction equilibria between sPEEK’s sulfonic acid groups and the basic sites of the added heterocycles. Using the copper-catalyzed 1,3-dipolar “click” cycloaddition reaction, poly(sulfone)s containing pendant azide moieties were functionalized with various amounts of sodium 3-(prop-2-ynyloxy)propane-1-sulfonate and crosslinked with 1,7-octadiyne. The degree of sulfonation as well as the degree of cross-linking was systematically varied by changing the ratios of the aforementioned reagents. The polymers were cast into membranes, acidified, and then tested for proton conductivity, methanol permeability, and membrane-electrode assembly (MEA) performance. / text Dynamic covalent polymers Self healing materials, reversible Conjugated polymers Direct methanol fuel cell membranes N-heterocyclic carbene Polytriazene

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