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11	SYNTHESIS AND CHARACTERIZATION OF ELASTOMER-BASED COMPOSITES AND POLYMER-IMMOBILIZED COLLOIDAL TRANSITION METAL NANOPARTICLES: CATALYTIC SELECTIVITY AND MORPHOLOGY VU, YEN THI 08 November 2001 (has links) No description available. Chemistry, Polymer clay, montmorillonite, nanolayers polypropylene, thermoplastic elastomers palladium nanoparticles, catalyst
12	Rheological and Mechanical behaviour of Block copolymers, Multigraft copolymers and Block copolymer Nanocomposites Thunga, Mahendra 07 July 2009 (has links) (PDF) Block copolymers are commercially significant and fundamentally interesting class of polymeric materials. The ability to undergo interfacial thermodynamics-controlled microphase separation from a completely disordered state in the melt to a specifically defined ordered structure through self-organization makes the block copolymers based materials unique. Block copolymer are strongly replacing many of the commercially available polymers due to their unique microstructure and properties. The most practical interests of block copolymers lie in the area of thermoplastic elastomers (TPEs). The objective of the present thesis work is to developing novel roots for enhancing the physical and mechanical properties in block copolymer and multigraft copolymers. Initially the properties are tailored by controlling chemical architecture at synthesis level and by selective blending at production level. This gives an easy access for improvement of the material properties and this is one of my major tasks in the present research modules. Further the block copolymer based TPEs are cross-linked in presence of electron beam (EB) radiation for developing materials with superior properties. The electron beam radiation has the ability to alter material parameters at molecular level for enhancing the macroscopic properties. The desirable physical and chemical properties can be easily attained by varying the radiation beam parameters. In addition to that, controlling the material at nanometer scale is one of the greatest challenges for current nanocomposite research. In elastomeric materials it is very prominent to fill the rubber matrix with nano particles from carbon or silica by melt mixing technique for enhancing the material properties. Other than conventional melt mixing technique, sol–gel processing is also a versatile technique, which making it possible to produce a wide variety of materials and to provide existing materials with novel properties. A combination of in situ sol-gel reaction with electron beam cross-linking in TPEs from triblock copolymer has been demonstrated for the first time as one of the novel nanocomposite system in this work. The main advantage of this system lies in controlling the material behaviour by finely tuning the size of silica nano particle generated inside TPE during in situ sol-gel reaction. Finally, the various roots employed for enhancing the material behaviour in block copolymers in the above research module were secussfully employed on super elastic multigraft copolymers for improving their strength withour sacrificing the super elastic nature. Block copolymers Nanocomposites Multigraft copolymers Cross-linking Rheology Electronbeam Thermoplastic Elastomers Blockcopolymere Nanokomposite Multipfropfcopolymere Vernetzung Rheologie Elektronenstrahl Thermoplastische Elastomere ddc:620 rvk:ZM 5300
13	Tailoring the mesoscopic structure and orientation of semicrystalline and liquid-crystalline polymers : from 1D- to 2D-confinement Odarchenko, Yaroslav 15 November 2012 (has links) (PDF) Controlling the micro-structure of organic materials is crucial for a variety of practical applications such as photonics, biomedicine or the rapidly growing field of organic electronics. Recent studies have shown a possibility of tailoring the polymer structure on the nanoscale using supramolecular self-assembly under spatial confinement. Despite extensive studies already performed in this field, many questions remain open. In particular, it will be important to understand how different structure formation processes such as crystallization, LC-phase formation, microphase separation, and others occur under confinement. In the present work, we address the effect of 1D- and 2D-confinement on the structure formation for a variety of systems including segmented poly(ether-ester-amide) (PEEA) copolymers, main-chain liquid-crystalline (LC) polymers belonging to the family of poly(di-n-alkylsiloxane)s and liquid-crystalline/semicrystalline block copolymers formed through complexation of poly (2-vinylpyridine-b-ethylene oxide) (P2VP-PEO) with a wedge-shaped ligand, 4'-(3'',4'',5''-tris(octyloxy) benzamido) propanoic acid. In order to reveal the morphological diversity of the studied systems under confinement, the work was carried out on bulk materials and on thin films employing a battery of experimental methods. The main experimental techniques operational in direct and reciprocal space applied in my work are described in chapter 2. [...] [CHIM:OTHE] Chemical Sciences/Other [CHIM:OTHE] Chimie/Autre Confinement Crystallization Phase separation Liquid crystalline polymers X-ray scattering Thermoplastic elastomers Semicrystalline polymers Thin films
14	Compósitos de termoplásticos com borracha natural reforçada com cinzas de bagaço de cana / Compuestos termoplásticos con caucho natural reforzado con cenizas de bagazo de caña Barrera Torres, Giovanni [UNESP] 21 June 2017 (has links) Submitted by GIOVANNI BARRERA TORRES null (gbarrerat01@gmail.com) on 2017-08-04T04:24:40Z No. of bitstreams: 1 TESE VERSÃO FINAL Giovanni Barrera Torres.pdf: 6197644 bytes, checksum: d321626a0e947c39627bbfe43b7aaf87 (MD5) / Approved for entry into archive by LUIZA DE MENEZES ROMANETTO (luizamenezes@reitoria.unesp.br) on 2017-08-04T19:37:47Z (GMT) No. of bitstreams: 1 torres_gb_dr_prud.pdf: 6197644 bytes, checksum: d321626a0e947c39627bbfe43b7aaf87 (MD5) / Made available in DSpace on 2017-08-04T19:37:47Z (GMT). No. of bitstreams: 1 torres_gb_dr_prud.pdf: 6197644 bytes, checksum: d321626a0e947c39627bbfe43b7aaf87 (MD5) Previous issue date: 2017-06-21 / Asociación Universitaria Iberoamericana de Postgrado (AIUP) / A presente pesquisa foi projetada para promover o desenvolvimento de compósitos poliméricos a partir da mistura de polietileno de baixa densidade (PEBD) com borracha natural (BN) reforçada com a cinza, resíduo da queima do bagaço, a cinza da cana de açúcar (CBC). Uma das propostas desta pesquisa foi direcionar uma aplicação ao resíduo, que é um material abundante e descartado, gerado no processo usual das usinas. A borracha natural empregada foi obtida a partir do látex de seringueira de Hevea Brasiliensis, Clone RRIM 600 muito cultivado no Brasil. A fim de se estudar separadamente a interação entre a CBC junto a BN e os agentes de vulcanização. Foi estudada numa primeira etapa: a mistura de borracha natural com a cinza de bagaço da cana até desenvolver uma mistura chamada de master, com boas propriedades de tensão e deformação. Foram produzidos compósitos elastoméricos aplicando agente silano como sistema de acoplamento. Numa segunda etapa o master compatibilizado foi misturado ao PEBD sem o uso de agentes de vulcanização; a finalidade destes compósitos foi de estudar a interação dos constituintes visando obter um compósito com o mínimo de agentes químicos e funcional para a indústria. Numa última etapa foram desenvolvidas blendas e compósitos termoplásticos vulcanizáveis (TPV); nesta etapa foram aplicados os agentes de vulcanização empregados na primeira etapa da pesquisa. As amostras foram estudadas por meio das técnicas de análises estruturais (FT-IR); físico-mecânicas (tensão e deformação; dinâmicas e mecânicas, DMA); térmicas (DSC e TG); dureza (Shore A). Foram obtidos resultados sobressalientes em comparação com as amostras sem agentes de vulcanização nas amostras com 50 % de master e 50 % de PEBD na resposta de elongação e tensão; a dureza acima do Shore A 85 obtida, foi produto da porcentagem da fase de PEBD presente nas amostras; nas análises térmicas foi possível observar degradação acima dos 160 oC resultando uma boa característica para aplicações industriais. Com os resultados obtidos tornou-se possível direcionar tanto a CBC como os compósitos para aplicações tecnológicas a fim de serem utilizados na fabricação de cabos de ferramentas, amortecedores, produtos para o lar, entre outros. / The present research was aimed to promote the development of polymeric composites from the mixture of low density polyethylene (LDPE) with natural rubber reinforced with ash, residue of the burning of sugarcane bagasse (SCB). One of the proposals of this research was to direct an application to the residue, which is an abundant and discarded material, generated in the usual process of the plants. The natural rubber used was obtained from rubber latex clone of Hevea Brasiliensis, Clone RRIM 600 widely cultivated in Brazil. In order to study separately the interaction between SCB with NR and vulcanization agents. It was developed in the first stage: the mixing of natural rubber with the sugarcane bagasse ash to develop a mixture called master, with good tensile and deformation properties. Elastomeric composites were produced by applying silane as a coupling agent. In a second stage the compatibilized master was mixed to the LDPE without the use of vulcanization agents; the purpose of these composites was to study the interaction of the constituents in order to obtain a composite with the minimum of chemical and functional agents for the industry. In the latter stage vulcanizable thermoplastic blends and thermoplastic composites were developed; In this stage the vulcanization agents used in the first stage of the research were applied. The samples were studied using structural analysis techniques (FT-IR); Physical-mechanical (tension and deformation, dynamic and mechanical, DMA); (DSC and TG); Hardness (Shore A). Sparing results were obtained in comparison with the samples without vulcanization agents in samples with 50 % of master and 50 % of LDPE in the strain and stress response; the hardness above Shore A 85, obtained was the product of the percentage of the LDPE phase present in the samples; In the thermal analyzes it was possible to observe degradation above 160 oC resulting in a good characteristic for industrial applications. With the results obtained, it became possible to target both SCB and composites for technological applications in order to be used in the manufacture of tool cables, shock absorbers, household products, among others. / AIUP: A0 185864 Elastômeros termoplásticos Borracha natural Polietileno de baixa densidade Blendas poliméricas Cinza de bagaço de cana-de-açúcar Compatibilização Thermoplastic elastomers Natural rubber Low density polyethylene Polymer blends Sugarcane bagasse ash Compatibility
15	Rheological and Mechanical behaviour of Block copolymers, Multigraft copolymers and Block copolymer Nanocomposites Thunga, Mahendra 18 June 2009 (has links) Block copolymers are commercially significant and fundamentally interesting class of polymeric materials. The ability to undergo interfacial thermodynamics-controlled microphase separation from a completely disordered state in the melt to a specifically defined ordered structure through self-organization makes the block copolymers based materials unique. Block copolymer are strongly replacing many of the commercially available polymers due to their unique microstructure and properties. The most practical interests of block copolymers lie in the area of thermoplastic elastomers (TPEs). The objective of the present thesis work is to developing novel roots for enhancing the physical and mechanical properties in block copolymer and multigraft copolymers. Initially the properties are tailored by controlling chemical architecture at synthesis level and by selective blending at production level. This gives an easy access for improvement of the material properties and this is one of my major tasks in the present research modules. Further the block copolymer based TPEs are cross-linked in presence of electron beam (EB) radiation for developing materials with superior properties. The electron beam radiation has the ability to alter material parameters at molecular level for enhancing the macroscopic properties. The desirable physical and chemical properties can be easily attained by varying the radiation beam parameters. In addition to that, controlling the material at nanometer scale is one of the greatest challenges for current nanocomposite research. In elastomeric materials it is very prominent to fill the rubber matrix with nano particles from carbon or silica by melt mixing technique for enhancing the material properties. Other than conventional melt mixing technique, sol–gel processing is also a versatile technique, which making it possible to produce a wide variety of materials and to provide existing materials with novel properties. A combination of in situ sol-gel reaction with electron beam cross-linking in TPEs from triblock copolymer has been demonstrated for the first time as one of the novel nanocomposite system in this work. The main advantage of this system lies in controlling the material behaviour by finely tuning the size of silica nano particle generated inside TPE during in situ sol-gel reaction. Finally, the various roots employed for enhancing the material behaviour in block copolymers in the above research module were secussfully employed on super elastic multigraft copolymers for improving their strength withour sacrificing the super elastic nature. info:eu-repo/classification/ddc/620 ddc:620
16	Elastomères silicones formulés pour l'amortissement / Silicone elastomers for damping applications Robeyns, Constance 13 April 2018 (has links) L’objectif de ces travaux de thèse est de générer de l’amortissement à matériaux silicones, et plus particulièrement de mettre en lumière les relations entre la structure des additifs incorporés dans la base silicone et la morphologie des mélanges, ainsi que leur densité de réticulation et leurs propriétés mécaniques et dynamiques. Une première étude bibliographique a permis de sélectionner les deux types d’additifs étudiés dans nos formulations, à savoir les élastomères silicones thermoplastiques (TPS) et les résines silicones. Les propriétés mécaniques de TPS commerciaux ou synthétisés en laboratoire, seuls et en blends avec une base silicone, ont été comparés selon le taux de TPS ainsi que sa structure. Les hypothèses sur les relations structure-propriétés des différents TPS se sont appuyées sur la bibliographie. L’influence du type de peroxyde et de sa concentration dans la formulation a également été étudiée. Les copolymères silicone-urée préparés avec un diisocyanate asymétrique et non aromatique présentent les amortissements les plus intéressants, une fois mis en mélange à un taux suffisant avec une base silicone et réticulés, tandis qu’un copolymère silicone-amide original montre un amortissement moindre mais à plus basse température. Dans tous les cas, le blend possèdant une faible densité de réticulation présente donc un meilleur amortissement. La deuxième voie d’étude concerne les résines silicones, et plus particulièrement les résines de type MQ et MQQOH. Dans un premier temps, les différentes structures de résines silicones décrites dans la bibliographie et leurs méthodes de synthèse ont été sériées. Dans un deuxième temps, des mélanges ont été réalisés en variant la structure et le taux de résines. Leur influence sur la densité du réseau ainsi que sur les propriétés mécaniques des matériaux après réticulation a été observée. Afin de pouvoir valider ou invalider des hypothèses, certaines résines ont été modifiées chimiquement, avant d’être ajoutées à la base silicone. Finalement, certains paramètres de la structure des résines ont été particulièrement considérés, comme un taux d’hydroxyle faible ou une masse molaire élevée. Le taux de résine dans la base joue un rôle important puisqu’il influe sur la densité de réticulation et sur les propriétés dynamiques du matériau une fois réticulé. / This PhD work aimed at improving the damping properties of silicones materials, and more specifically at highlithing the relationships between the structure of additives in a silicone base and the morphology of the blends, as well as their crosslink density and mechanical and dynamical properties. A preliminary literature survey allowed selecting two types of additives for further formulation: thermoplastic elastomers (TPS) and silicone resins. The mechanical properties of commercial or hand-made TPS, alone or blended with a silicone base, were compared according to the structure of the TPS or its content in the blend. Hypotheses were made about the structure-properties relationships of the different TPS tested, and these hypotheses were confirmed or rejected with the help of literature. The role played by the peroxide type or content was also investigated. It appeared that poly(silicone-urea) copolymers containing non-symmetrical hard segments display better damping properties, especially when they blended at a sufficient content in the silicone base. Blends of silicone base and original silicone-amide copolymers showed lower damping properties but at lower temperature. The damping properties were enhanced when using peroxides that led to a low crosslink density. The second route relates to silicone resins, and more specifically MQ or MQQOH resins. First of all, an inventory of the different structures of silicones resins, as well as their synthesis methods, available in literature was carried out. Next, several blends were prepared by varying the structure or the content of silicone resins, and their influence on the crosslink density or mechanical properties of the final materials was investigated. Some resins were modified in order to validate or reject some hypotheses, such as the influence of the hydroxyl content in the resins or the molar mass. Among the main parameters to obtain damping silicone materials, the crosslink density, influenced by the resin content, plays a major role in the dynamic properties of the crosslinked material. Matériaux Elastomères silicones Résines silicones Elastomères thermoplastiques Amortissement Relation structure propriétés Materials Silicone rubber Silicone resins Thermoplastic elastomers Damping Structure properties relationship 620.194 072
17	Élaboration d'élastomères silicones supramoléculaires auto-cicatrisants / Design of self-healing supramolecular silicone elastomers Fauvre, Lucile 13 December 2018 (has links) Ces travaux de thèse concernent l’étude de matériaux supramoléculaires en vue de générer de nouveaux élastomères silicones auto-cicatrisants. Dans un premier temps, l’étude de la bibliographie a permis de recenser les différentes voies intégrant de la chimie supramoléculaire développées dans le domaine des silicones et basées sur les liaisons hydrogène. L’effet des groupements associatifs sur les propriétés rhéologiques et mécaniques des matériaux a été discuté, et les limitations de ces systèmes soulignées. La chimie développée par l’équipe du Dr. Leibler, adaptée par la suite aux silicones par le Pr. Zhang et son équipe, a particulièrement été analysée lors de notre étude de compréhension. Les relations structures/propriétés n’étaient pas clairement élucidées à l’issue de cette étude de la bibliographie. Des études modèles impliquant un PDMS téléchélique aminé ainsi que de l’urée ont donc été réalisées. La caractérisation précise des structures des produits de réaction a permis de mettre en exergue certaines corrélations entre structures (choix du groupement associant, masse molaire du copolymère, fonctionnalité) et propriétés (rhéologiques et mécaniques) qui n’avaient alors pas été démontrées pour ces systèmes. Il a aussi été montré que la force des groupements et les enchevêtrements jouent un rôle primordial. Une chimie différente, inspirée des travaux de Yilgör et al sur les copolymères segmentés, a par la suite été envisagée, en mettant en jeu cette fois la réaction d’aza-Michael. Cette synthèse se démarque du premier système par un meilleur contrôle de la structure macromoléculaire finale. Un silicone supramoléculaire élastomère et auto-cicatrisant a été obtenu en combinant une fonctionnalité importante et une masse molaire finale élevée. Les propriétés mécaniques de ce polymère ont été optimisées par l’ajout de charges plus ou moins renforçantes. L’impact d’un tel renfort sur les propriétés auto-cicatrisantes du système a été discuté. / This PhD thesis focused on the investigation of supramolecular materials in order to generate new self-healing supramolecular silicone elastomers. Firstly, a literature review on silicone materials was realized and we identified the different ways developed in the silicone domain that imply supramolecular chemistry and in particular hydrogen-bonds. The influence of associating groups on rheological and mechanical properties of these materials was discussed, and the restrictions of such systems were highlighted. The chemistry developed by Dr. Leibler and co-workers, later adapted to silicones by Pr Zhang and his team, was deeply investigated during our comprehension study. Relationships between structure and properties were nonetheless not fully elucidated in these studies. Model reactions involving telechelic amino-PDMS and urea were then carried out. The thorough characterization of the final structure of the reaction products highlighted few correlations between structural parameters (choice of the type of associating group, molecular weight of copolymer, functionality) and properties (rheological and mechanical) that had not been demonstrated yet for these systems. We showed that, among others, the strength of the associating groups as well as the entanglements play a fundamental role. A different chemistry, inspired by Yilgör and co-workers’ studies on segmented copolymers, was later considered by carrying out an aza-Michael reaction. This synthesis differs from the previous one by its better control of the final macromolecular structure. A supramolecular silicone elastomer with self-healing abilities was obtained by combining a large functionality together with a high final molecular weight. Mechanical properties of this material were further enhanced through the addition of more or less reinforcing fillers. The influence of such reinforcement on self-healing capacity of this system was discussed. Matériaux supramoléculaires Elastomères thermoplastiques Pdms Urée Isocyanate-Free Auto_cicatrisation Charges renforçantes Supramolecular materials Thermoplastic elastomers Pdms Urea Isocyanate-Free Self-Healing Reinforcing fillers 620.194 072
18	New Applications for Linear and Arborescent Polyisobuylene-Based Thermoplastic Elastomers Charif Rodriguez, Andrea Carolina 21 May 2015 (has links) No description available. Polymer Chemistry Polymers Materials Science
19	Tailoring the mesoscopic structure and orientation of semicrystalline and liquid-crystalline polymers : from 1D- to 2D-confinement / Adapter la structure mésoscopique et l'orientation des polymères semi-cristallins et des polymères de cristaux liquides : confinement à 1D et 2D Odarchenko, Yaroslav 15 November 2012 (has links) Le contrôle de la microstructure des matériaux organiques est crucial pour des applications pratiques telles que la photonique, la biomédecine ou encore le domaine très dynamique de l'électronique organique. Les études récentes ont montré une possibilité de contrôler la structure des polymères à l'échelle nanométrique en utilisant l'auto-assemblage supramoléculaire sous confinement spatial. Bien que de nombreuses études ont déjà été effectuées dans ce domaine, plusieurs questions essentielles restent ouvertes. En particulier, il est important de comprendre comment les différents processus de formation structurale tels que la cristallisation, la formation d`une phase cristal liquide et la séparation de phases se déroulent sous confinement. Dans le présent travail, nous abordons l'effet du confinement à 1D et à 2D sur la formation de la structure pour une variété de systèmes, y compris les copolymères segmentés de poly(éther-ester-amide) (PEEA), les polymères cristaux liquides (CL) dont la chaîne principale appartient à la famille des poly(di-n-alkylsiloxane)s et des copolymères à bloc cristaux-liquides /semicristallins formés par complexation de poly(2-vinylpyridine-b-oxyde d'éthylène) (P2VP-PEO) avec un ligand cunéiforme, l'acide 4'-(3'',4'',5''-tris(octyloxy) benzamido) propanoïque. Pour être capable de traiter de façon adéquate la morphologie complexe de ces systèmes sous confinement, le travail a été effectué en utilisant une batterie de méthodes expérimentales. Les techniques principales opérationnelles dans l'espace direct et réciproque que nous avons employées sont décrites dans le chapitre 2. [...] / Controlling the micro-structure of organic materials is crucial for a variety of practical applications such as photonics, biomedicine or the rapidly growing field of organic electronics. Recent studies have shown a possibility of tailoring the polymer structure on the nanoscale using supramolecular self-assembly under spatial confinement. Despite extensive studies already performed in this field, many questions remain open. In particular, it will be important to understand how different structure formation processes such as crystallization, LC-phase formation, microphase separation, and others occur under confinement. In the present work, we address the effect of 1D- and 2D-confinement on the structure formation for a variety of systems including segmented poly(ether-ester-amide) (PEEA) copolymers, main-chain liquid-crystalline (LC) polymers belonging to the family of poly(di-n-alkylsiloxane)s and liquid-crystalline/semicrystalline block copolymers formed through complexation of poly (2-vinylpyridine-b-ethylene oxide) (P2VP-PEO) with a wedge-shaped ligand, 4'-(3'',4'',5''-tris(octyloxy) benzamido) propanoic acid. In order to reveal the morphological diversity of the studied systems under confinement, the work was carried out on bulk materials and on thin films employing a battery of experimental methods. The main experimental techniques operational in direct and reciprocal space applied in my work are described in chapter 2. [...] Confinement Cristallisation Séparation des phases Polymères cristallins liquides Diffusion des rayons-X Élastomères thermoplastiques Polymères semi-cristallins Films minces Confinement Crystallization Phase separation Liquid crystalline polymers X-ray scattering Thermoplastic elastomers Semicrystalline polymers Thin films 540
20	Applications of Styrenic Thermoplastic Elastomers in Stimuli Responsive Dynamically Porous Materials and Ice Anti-Slip Composites Namdari, Navid January 2021 (has links) No description available. Engineering Materials Science Mechanical Engineering Polymers Thermoplastic elastomers responsive polymers optical functional polymers slip-resistance winter safety surface texturing ice traction nanocomposite surfaces

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