Global ETD Search

51	Oligomères dihydroxytéléchéliques à basse Tg et stabilité accrue : élaboration par métathèse et optimisation des propriétés pour application dans le domaine spatial / Dihydroxytelechelic oligomers with low Tg and improved stability : synthesis via metathesis and optimization for further use in spatial applications. Lucas, Frédéric 24 November 2008 (has links) L´objectif du travail présenté dans ce manuscrit consiste à conserver les bonnes propriétés mécaniques du poly(butadiène) dihydroxytéléchélique (PBHT) tout en améliorant sa stabilité. Un des principaux verrous techniques de cette approche réside dans le fait que les doubles liaisons responsables la flexibilité du matériau sont également la cause de son vieillissement par oxydation. Les solutions proposées reposent sur l´utilisation de la métathèse comme outils de synthèse de polymères insaturés. Deux grandes voix de synthèse ont été étudiées : la polymérisation par ouverture de cycle via métathèse (ROMP) ainsi que la dépolymerisation fonctionnalisante (ADMET). Ces deux approches bien que prometteuses n’ont pas permis de sortir de la relation ciseau existante entre flexibilité et stabilité. Finalement, une solution basée sur le mélange entre deux polymères dihydroxytéléchéliques de basse température de transition vitreuse – poly(butadiene) et poly(isobutylene) a permis de répondre dans une certaine mesure aux cahier des charges. En parallèle a ces parties synthèses, une étude physique des relations structure-propriétés visant à améliorer la stabilité des oligomères a été apporté par mesure rhéologique du temps critique de réticulation. / The work reported in the following document is aiming at maintaining the good mechanical properties of diHydroxyTelechelic PolyButadiene HTPB while improving its stability. The major challenge of this approach is that the unsaturations responsible for the outstanding flexibility of the material are also rather sensitive to oxidation. The solutions presented in this study are based on the use of metathesis reactions as a tool for the design of new difunctional unsaturated oligomers. Two functionalization techniques have been investigated, on the one hand, the Ring Opening Methathesis Polymerisation (ROMP) and, on the other hand, the depolymerisation via Acyclic Diene METathesis (ADMET). Although promising, the latters proved to fall into the vicious circle consisting in simultaneously increasing the stability while losing the flexibility. Finally, a blending concept based on the mixture of two dihydroxytelechelic polymers, namely, poly(isobutylene) and poly(butadiene), could enable us to achieve our initial goal. In addition to the chapters focusing on polymer chemistry and synthesis, a physical study of the parameters influencing the aging of unsaturated oligomers have been set-up and the properties relationship using measurements of the critical time. Métathèse PBHT Poly(butadiéne) Poly(isobutylene) Stabilité Vieillissement ADMET ROMP Température de transition vitreuse Propergol Metathesis PBHT Poly(isobutene) Stability Aging ADMET ROMP Glass transition temperature Propellant
52	Synthesis of selected cage alkenes and their attempted ring-opening metathesis polymerisation with well-defined ruthenium carbene catalysts / Justus Röscher Röscher, Justus January 2011 (has links) In this study a number of cage alkenes were synthesised and tested for activity towards ringopening metathesis polymerisation (ROMP) with the commercially available catalysts 55 (Grubbs-I) and 56 (Grubbs-II). The first group of monomers are derivatives of tetracyclo[6.3.0.04,1105,9]undec-2-en-6-one (1). The synthesis of these cage alkenes are summarised in Scheme 7.1. The cage alkene 126b was synthesised by a Diels-Alder reaction between 1 and hexachlorocyclopentadiene (9, Scheme 7.2). The geometry of 126b was determined from XRD data. Knowledge of the geometry of 126b also established the geometry of 127 since conformational changes during the conversion from 126b to 127 are unlikely. Synthesis of the cage alkene 125 by the cycloaddition of 9 to 118 failed. The cage alkene exo-11- hydroxy-4,5,6,7,16,16-hexachlorohexacyclo[7.6.1.03,8.02,13.010,14]hexa-dec-5-ene (124, Scheme 7.3) could therefore not be prepared. Synthesis of 125 by reduction of 126b with various reduction systems was not successful. Theoretical aspects of these reactions were investigated with molecular modelling. A possible explanation for the unreactive nature of 126b towards reduction is presented, but the lack of reactivity of 118 towards 9 eluded clear explanations. The synthesis of cage alkenes from 4-isopropylidenepentacyclo[5.4.0.02,6.03,10.05,9]-undecane-8,11- dione (23) did not meet with much success (Scheme 7.4). Numerous synthetic methods were investigated to affect the transformation from 134a/134b to 135 (Scheme 7.5). These attempts evolved into theoretical investigations to uncover the reasons for the observed reactivity. Possible explanations were established by considering the differences and similarities between the geometries and electronic structures of reactive and unreactive cage alcohols. ROMP of cage monomers based on 1 were mostly unsuccessful. Only the cage monomer 127 showed some reactivity. Endocyclic cage monomers with a tetracycloundecane (TCU) framework showed no reactivity. The results from NMR experiments verified the experimental results. Hexacyclo[8.4.0.02,9.03,13.04,7.04,12]tetradec-5-en-11,14-dione (3) exhibited notable ROMP reactivity. Examination of the orbitals of the cage alkenes used in this study suggested that the reactivity of 1 and 3 could possibly be enhanced by removal of the carbonyl groups. Decarbonylation of 1 and 3 yielded the cage hydrocarbons 159 and 175, respectively. ROMP tests revealed that 175 is an excellent monomer, but 159 was unreactive. The results obtained for the ROMP reactions in this study was rationalised by considering aspects such as ring strain, energy profiles, steric constraints, and frontier orbital theory. The concept of ring strain is less useful when describing the reactivity of cage alkenes towards ROMP and therefore the concepts of fractional ring strain and fractional ring strain energy (RSEf) were developed. A possible link between RSEf and the ROMP reactivity of cage alkenes was also established. The following criteria were put forth to predict the reactivity or explain the lack of reactivity of cage alkenes towards ROMP reactions with Grubbs-I and Grubbs-II. The criteria for ROMP of cage monomers: 1. Sufficient fractional ring strain energy (RSEf). 2. A reasonable energy profile when compared to a reference compound such as cyclopentene. 3. Ability to form a metallacyclobutane intermediate with reasonable distances between different parts of the cage fragment. 4. Sufficient ability of the polymer fragment to take on a conformation that exposes the catalytic site. 5. Sufficient size, shape, orientation and energy of HOMO and/or NHOMO at the alkene functionality of the cage monomer and of the LUMO at the catalytic site. / Thesis (Ph.D. (Chemistry))--North-West University, Potchefstroom Campus, 2012 Cage alkenes Cage compounds Ring-opening metathesis polymerisation ROMP Ruthenium carbene catalysts Grubbs-I Grubbs-II
53	Synthesis of selected cage alkenes and their attempted ring-opening metathesis polymerisation with well-defined ruthenium carbene catalysts / Justus Röscher Röscher, Justus January 2011 (has links) In this study a number of cage alkenes were synthesised and tested for activity towards ringopening metathesis polymerisation (ROMP) with the commercially available catalysts 55 (Grubbs-I) and 56 (Grubbs-II). The first group of monomers are derivatives of tetracyclo[6.3.0.04,1105,9]undec-2-en-6-one (1). The synthesis of these cage alkenes are summarised in Scheme 7.1. The cage alkene 126b was synthesised by a Diels-Alder reaction between 1 and hexachlorocyclopentadiene (9, Scheme 7.2). The geometry of 126b was determined from XRD data. Knowledge of the geometry of 126b also established the geometry of 127 since conformational changes during the conversion from 126b to 127 are unlikely. Synthesis of the cage alkene 125 by the cycloaddition of 9 to 118 failed. The cage alkene exo-11- hydroxy-4,5,6,7,16,16-hexachlorohexacyclo[7.6.1.03,8.02,13.010,14]hexa-dec-5-ene (124, Scheme 7.3) could therefore not be prepared. Synthesis of 125 by reduction of 126b with various reduction systems was not successful. Theoretical aspects of these reactions were investigated with molecular modelling. A possible explanation for the unreactive nature of 126b towards reduction is presented, but the lack of reactivity of 118 towards 9 eluded clear explanations. The synthesis of cage alkenes from 4-isopropylidenepentacyclo[5.4.0.02,6.03,10.05,9]-undecane-8,11- dione (23) did not meet with much success (Scheme 7.4). Numerous synthetic methods were investigated to affect the transformation from 134a/134b to 135 (Scheme 7.5). These attempts evolved into theoretical investigations to uncover the reasons for the observed reactivity. Possible explanations were established by considering the differences and similarities between the geometries and electronic structures of reactive and unreactive cage alcohols. ROMP of cage monomers based on 1 were mostly unsuccessful. Only the cage monomer 127 showed some reactivity. Endocyclic cage monomers with a tetracycloundecane (TCU) framework showed no reactivity. The results from NMR experiments verified the experimental results. Hexacyclo[8.4.0.02,9.03,13.04,7.04,12]tetradec-5-en-11,14-dione (3) exhibited notable ROMP reactivity. Examination of the orbitals of the cage alkenes used in this study suggested that the reactivity of 1 and 3 could possibly be enhanced by removal of the carbonyl groups. Decarbonylation of 1 and 3 yielded the cage hydrocarbons 159 and 175, respectively. ROMP tests revealed that 175 is an excellent monomer, but 159 was unreactive. The results obtained for the ROMP reactions in this study was rationalised by considering aspects such as ring strain, energy profiles, steric constraints, and frontier orbital theory. The concept of ring strain is less useful when describing the reactivity of cage alkenes towards ROMP and therefore the concepts of fractional ring strain and fractional ring strain energy (RSEf) were developed. A possible link between RSEf and the ROMP reactivity of cage alkenes was also established. The following criteria were put forth to predict the reactivity or explain the lack of reactivity of cage alkenes towards ROMP reactions with Grubbs-I and Grubbs-II. The criteria for ROMP of cage monomers: 1. Sufficient fractional ring strain energy (RSEf). 2. A reasonable energy profile when compared to a reference compound such as cyclopentene. 3. Ability to form a metallacyclobutane intermediate with reasonable distances between different parts of the cage fragment. 4. Sufficient ability of the polymer fragment to take on a conformation that exposes the catalytic site. 5. Sufficient size, shape, orientation and energy of HOMO and/or NHOMO at the alkene functionality of the cage monomer and of the LUMO at the catalytic site. / Thesis (Ph.D. (Chemistry))--North-West University, Potchefstroom Campus, 2012 Cage alkenes Cage compounds Ring-opening metathesis polymerisation ROMP Ruthenium carbene catalysts Grubbs-I Grubbs-II
54	Conception synthèse de surfaces nanostructurées et/ou fonctionnalisées par des nanoparticules comme système de ciblage cellulaire Forget, Guillaume 09 February 2009 (has links) La biocompatibilité d'un implant est principalement contrôlée par l'interface entre le biomatériau et le tissu environnant. Afin de contrôler cette interaction et de favoriser l'adhésion des cellules sur l'implant, nous avons créé à la surface d'alliages de titane des domaines nanométriques concentrés en séquence Arginine-Glycine-Acide Aspartique (RGD) reconnue pour ses propriétés adhésives. Après avoir modifié la chimie de surface par un agent de liaison aminosilane, nous avons utilisé les méthodes de synthèse de dendrimères ou liés des nanoparticules à l'aminosilane afin de démultiplier le nombre de amines primaires par site. Ces amines primaires étant ensuite utilisées pour attacher la séquence RGD à la surface du matériau. L'adhésion d'ostéoblastes sur les matériaux préparés a été étudié par acoustique picoseconde. / Abstract Biomatériau Titane Silane Nanodomaines Adhésion cellulaire Nanoparticules Hydrosilylation Romp Biocapteur Acoustique picoseconde Xps Aptes
55	Complexos de rutênio(II) coordenados à Bases de Schiff derivadas de cicloalquilaminas como precursores catalíticos para ROMP de norborneno e ATRP de metacrilato de metila / Ruthenium(II) complexes of Schiff base derived from cycloalkylamines as pre-catalysts for ROMP of norbornene and ATRP of methyl methacrylate Afonso, Maria Beatriz Alves [UNESP] 12 May 2017 (has links) Submitted by MARIA BEATRIZ ALVES AFONSO null (mbaafonso@hotmail.com) on 2017-06-12T21:05:33Z No. of bitstreams: 1 Dissertação_ Maria Beatriz Alves Afonso.pdf: 2111821 bytes, checksum: 42668991264b1d02752d3be1fc9cc953 (MD5) / Approved for entry into archive by Luiz Galeffi (luizgaleffi@gmail.com) on 2017-06-13T17:19:35Z (GMT) No. of bitstreams: 1 afonso_mba_me_sjrp.pdf: 2111821 bytes, checksum: 42668991264b1d02752d3be1fc9cc953 (MD5) / Made available in DSpace on 2017-06-13T17:19:35Z (GMT). No. of bitstreams: 1 afonso_mba_me_sjrp.pdf: 2111821 bytes, checksum: 42668991264b1d02752d3be1fc9cc953 (MD5) Previous issue date: 2017-05-12 / Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES) / A investigação de sistemas catalíticos duais capazes de mediar as reações de polimerização por abertura de anel via metátese (ROMP) e de polimerização radicalar por transferência de átomo (ATRP) simultaneamente é de grande interesse e importância na obtenção de novos materiais com potencial de aplicação. Neste estudo, novos complexos de rutênio(II) coordenados a diferentes bases de Schiff derivadas de cicloalquilaminas (ciclopentil 1a, cicloexil 1b, cicloheptil 1c e ciclooctil 1d) foram sintetizados: [RuCl(CyPen-Salen)(PPh3)2] 2a, [RuCl(CyHex-Salen)(PPh3)2] 2b, [RuCl(CyHep-Salen)(PPh3)2] 2c e [RuCl(CyOct-Salen)(PPh3)2] 2d. As bases de Schiff e seus respectivos complexos de rutênio foram caracterizados por FTIR, UV-Vis, RMN e voltametria cíclica. Os complexos planejados foram avaliados como precursores catalíticos em reações de ROMP de norborneno (NBE) e em reações de ATRP de metacrilato de metila (MMA). As sínteses de polinorborneno (poliNBE) via ROMP com os complexos 2a-d como pré-catalisadores foram avaliadas sob diferentes condições de reação ([HCl]/[Ru], [EDA]/[Ru], [NBE]/[Ru] e temperatura). Os melhores rendimentos de poliNBE foram obtidos a 50 °C com razão molar [NBE]/[HCl]/[Ru] = 5000/25/1 na presença de 5 µL de EDA por 60 minutos. A polimerização de MMA via ATRP foi conduzida usando os complexos 2a-d na presença de etil-α-bromoisobutirato (EBiB) como iniciador. Os testes catalíticos foram avaliados em função do tempo de reação usando a razão molar [MMA]/[EBiB]/[Ru] = 1000/2/1. Todos os experimentos via ATRP foram conduzidos à 85 °C. A correlação linear do ln([MMA]0/[MMA]) em função do tempo na ATRP de MMA mediada pelos complexos 2a-d indica que a concentração de radicais permanece constante durante a polimerização. As massas moleculares aumentaram linearmente com a conversão com a diminuição dos valores de IPD, no entanto, as massas moleculares experimentais foram maiores do que as massas moleculares teóricas. / The investigation of dual catalytic systems able to mediate simultaneously ring-opening metathesis polymerization (ROMP) and atom-transfer radical polymerization (ATRP) reactions is of great interest and importance in obtaining new materials with potential for application. In the study, ruthenium(II) complexes of Schiff base derived from cycloalkylamines (cycloalkyl = cyclopentyl 1a, cyclohexyl 1b, cycloheptyl 1c and cyclooctyl) 1d were synthesized: [RuCl(CyPen-Salen)(PPh3)2] 2a, [RuCl(CyHex-Salen)(PPh3)2] 2b, [RuCl(CyHep-Salen)(PPh3)2] 2c and [RuCl(CyOct-Salen)(PPh3)2] 2d. The Schiff bases 1a-d and their respective RuII complexes 2a-d were characterized by FTIR, UV-Vis, NMR, and cyclic voltammetry. The complexes 2a-d were evaluated as catalytic precursors for ROMP of norbornene (NBE) and for ATRP of methyl methacrylate (MMA). The syntheses of polynorbornene (polyNBE) via ROMP with complexes 2a-d as pre-catalysts were evaluated under different reaction conditions ([HCl]/[Ru], [EDA]/[Ru], [NBE]/[Ru], and temperature). The highest yields of polyNBE were obtained with [NBE]/[HCl]/[Ru] = 5000/25/1 molar ratio in the presence of 5 µL of EDA for 60 minutes at 50 °C. MMA polymerization via ATRP was conducted using the complexes 2a-d in the presence of ethyl-α-bromoisobutyrate (EBiB) as initiator. The catalytic tests were evaluated as a function of the reaction time using the initial molar ratio of [MMA]/[EBiB]/[Ru] = 1000/2/1 at 85 °C. The linear correlation of ln([MMA]0/[MMA]) and time clearly indicates that the concentration of radicals remains constant during the polymerization and that the ATRP of MMA mediated by 2a-d proceeds in a controlled manner. Molecular weights increased linearly with conversion, however, the experimental molecular weights were higher than the theoretical ones. Base de Schiff Rutênio Catalisador dual ROMP ATRP Schiff base Ruthenium Dual catalyst
56	Chemically Recyclable Polymers from Living ROMP of Cyclooctene Derivatives Shi, Zhen 28 April 2021 (has links) No description available. Polymers Polymer Chemistry ROMP depolymerizable polymers cyclooctene derivatives chemically recyclable polymers
57	Investigating the fundamentals of ring-opening metathesis polymerization to synthesize large, well-defined, bottlebrush polymers Blosch, Sarah Elizabeth 22 August 2022 (has links) Ring-opening metathesis polymerization (ROMP) is a robust synthetic technique for synthesizing complex polymer architectures (topologies). To achieve complex architectures, specifically bottlebrush polymers, using ROMP, attaining the highest degree of living character is essential. As the molecular weight of the side chain or backbone increases, the "livingness" of the polymerization suffers due to premature catalyst degradation. Attaining large, well-defined, bottlebrush polymers requires precision so it was our goal to determine how seemingly simple reaction variables could affect the rates of propagation and achievable conversion, as well as why these variables have these effects. We tested several reaction parameters to understand how they affect the rate of polymerization, the rate of catalyst degradation, and the conversion that can be reached. We performed a systematic study using six organic solvents to determine the propagation rate of three macromonomers (MMs), one polystyrene and two poly(n-butyl acrylate) MMs, in ROMP with varying side chain chemistries and end groups, as well as rate of catalyst degradation in each of the solvents. We determined that solvent affected that rate of propagation primarily by interacting with the catalyst, while there was some evidence of polymer sidechain chemistry affecting the rate. We found that ethyl acetate (EtOAc) and CH2Cl2 had the highest rates of propagation compared to the other solvents, while DMF and THF were the slowest. UV-Vis testing on the catalyst in each solvent revealed that DMF and THF had fast rates of catalyst decomposition, while toluene was much slower to decompose. From these experiments we learned that toluene, despite its slower propagation rate, has the most living character, due to its slower rate of decomposition. We also learned that purification greatly affects the propagation rate, with THF requiring purification to have any conversion to bottlebrush polymer, while purification of EtOAc slows the rate of propagation almost 2-fold. From the decrease in rate after purification, and the conclusion that it was due to an acetic acid impurity in the impure EtOAc, we decided to systematically test small molecule additives and found that acids can increase the propagation rate and the conversion of the polynorbornene backbone achievable in ROMP reactions. Notably, in reactions performed in DMF with added CF3COOH we were able to polymerize a norbornene-functionalized unprotected peptide, which was insoluble in most organic solvents, to a higher conversion than in DMF without the added acid. We learned from our research that changing reaction variables can lead to substantial changes in the rate of propagation as well as the achievable conversion in bottlebrush polymer synthesis. By understanding this we can further test other reaction variables and do systematic studies on atmosphere and temperature. We hope this research and future fundamental research can guide scientists toward synthesizing large, well-defined, complex polymer architectures using ROMP. / Doctor of Philosophy / Nature has shown that complex molecular architectures lead to unique material properties. This has inspired scientists to synthetically mimic nature to create these polymer architectures in an effort to obtain novel material properties. Ring-opening metathesis polymerization (ROMP) has become a powerful synthetic method for synthesizing complex polymer architectures. Specifically, ROMP has been used to synthesize bottlebrush polymers, so named due to the polymer backbone with long, densely grafted, polymer side chains attached. These materials exhibit very interesting properties compared to their linear polymer counterparts. Using ROMP to synthesize bottlebrush polymers is not uncommon; however, difficulties can arise if trying to use sidechains that are very long or bulky. We have worked to understand how manipulating some of the reaction parameters can allow us, and other researchers, to synthesize bottlebrush polymers that contain long and/or bulky polymer side chains. We tested the purity and type of solvent that the reaction was performed in on one polystyrene macromonomer and two poly(n-butyl acrylate) macromonomers, as well as adding small molecules, including acids, bases, and salts, to determine if these variables could improve the synthesis of bottlebrush polymers. What we found was that all of the tested variables, solvent, purity, additives, and combinations of all of these variables, did have an effect on the synthesis of these materials. This fundamental information will assist our lab, and many others, in efficiently synthesizing complex architectures, thus achieving unique material properties. kinetics rate half-life propagation termination
58	Couplage ROMP et ATRP en milieu dispersé aqueux : préparation et étude morphologique de particules polymères composites Airaud, Cédric 16 December 2008 (has links) Le confinement de polymères incompatibles au sein de particules induit une séparation de phase et conduit à la formation de morphologies particulières (cœur-écorce, hémisphérique…). Cette nanostructuration est à l’origine de propriétés de filmification particulières qui justifient l’utilisation des particules polymères composites dans le cadre d’applications comme la formulation de peintures ou de revêtements. Ce travail s’intéresse au développement d’approches permettant de préparer ces particules polymères composites en une seule étape et en milieu aqueux. La stratégie proposée repose sur le couplage « en simultané » de deux polymérisations distinctes: la polymérisation de cyclooléfines par métathèse (ROMP) et la polymérisation radicalaire par transfert d’atome (ATRP). Après avoir mis en évidence les difficultés liées au couplage de la ROMP et de l’ATRP en milieu dispersé aqueux, deux approches originales faisant intervenir respectivement des conditions de miniémulsion et de microémulsion sont proposées. Pour chacune d’elles, la présentation du principe de la synthèse et l’analyse de ses résultats précèdent l’étude morphologique des particules produites. / So as to broaden the scope of their applications in paints, coatings and impact-resistant plastics, many investigations have been dedicated to the preparation of nanostructured colloids over the past decades. Original morphologies including core-shell, hemispherical and complex occluded structures (raspberry-like, golf ball-like, octopus-like) can now be readily prepared. This work proposes a new straightforward one-pot, one-step, one-catalyst strategy to prepare polymer composite particles based on the simultaneous combination of two mechanistically distinct polymerizations in aqueous dispersed media. Norbornene (NB) and methyl methacrylate (MMA) were converted via Ring-Opening Metathesis Polymerization (ROMP) and Atom-Transfer Radical Polymerization (ATRP), respectively. Two original routes, designed to ensure simultaneous ROMP and ATRP, respectively under mini- and microemulsion conditions, are proposed. Both are successively reviewed on chemical and colloidal levels. Specific attention is paid to the morphologies of the prepared particles. Polymérisation par métathèse ROMP ATRP Particules polymères composites Milieu dispersé Miniémulsion Microémulsion Ring-opening Metathesis polymerization ROMP Atom-transfer radical polymerization ATRP Polymer composite particles Dispersed media Miniemulsion Microemulsion
59	Synthèse, caractérisation et polymérisation par ouverture de cycle par métathèse de macromonomères cyclobuténiques obtenus par chimie « click » et polymérisation RAFT / Synthesis, characterization, ring-opening metathesis polymerization of cyclobutenyl macromonomers obtained by "click" chemistry and RAFT polymerization Le, Dao 20 September 2012 (has links) Ce travail de thèse porte sur la synthèse de copolymères greffés à squelette 1,4-polybutadiène (PBu) et polyoxanorbornène par combinaison de ROMP et chimie click et/ou polymérisation RAFT selon la méthode grafting through. Une gamme de macromonomères symétriques et non symétriques originaux poly(oxyde d’éthylène) (POE), poly(acrylate d’éthyle), poly(acrylamide de N-isopropyle) (PNIPAM) et POE-b-PNIPAM ont été synthétisés à partir de précurseurs oxanorbornène et cyclobutène fonctionnalisés présentant un ou deux groupements clickables et/ou un agent RAFT par chimie click et polymérisation RAFT. Une série de PBu-g-POE et polyoxanorbornène-g-POE bien définis ont été obtenus par ROMP en solution en utilisant des amorceurs de Grubbs et de Schrock. Les tests de ROMP en milieu aqueux dispersé ont montré que la mini-émulsion était efficace pour la polymérisation des macromonomères POE à extrémité cyclobutényle et oxanorbornényle. / The objective of this thesis is the preparation and characterization of well-defined graft copolymers with 1,4 polybutadiene (PBu) backbone and polyoxanorbornene backbone by combination of ROMP and “click” reaction and/or RAFT polymerization according to the “grafting through” method. A series of new symmetrical or non-symmetrical poly(ethylene oxide) (PEO), poly(ethyl acrylate), poly(N-isopropylacrylamide) (PNIPAM) and PEO-b-PNIPAM macromonomers was prepared by “click” reaction and/or RAFT polymerization from cyclobutenyl and oxanorbornenyl precursors -containing “click-able” groups and/or a RAFT agent. A series of polyoxanorbornene-g-PEO and PBu-g-PEO with low PDIs has been obtained by ROMP in solution using the Grubbs or the Schrock catalysts. The ROMP in dispersed aqueous media showed that the mini-emulsion conditions were efficient for the polymerization of both oxanorbornenyl- and cyclobutenyl-functionalized PEO macromonomers. Copolymères greffés 1,4-Polybutadiène Polyoxanorbornène « Grafting through » Chimie « click » Polymérisation RAFT ROMP Graft copolymers 1,4-Polybutadiene Polyoxanorbornene Grafting through “Click” reaction RAFT polymerization ROMP
60	Towards designing composite membranes for CO2 separation : the inclusion of hybrid TiO2-PEG structures and study of their interfaces / Vers la conception de membranes composites pour la séparation du CO2 : Inclusion de structures hybrides TiO2-PEG et études de leurs interfaces Cao, Edgar 26 October 2015 (has links) Ce travail de thèse vise à concevoir de nouvelles membranes performantes pour la séparation de gaz (CO2) dans le procédé de post-combustion. La stratégie proposée repose sur la préparation de membranes hybrides organiques/inorganiques, combinant des supports poreux de dioxyde de titane (TiO2) intégrés dans une couche dense de polymère à base de poly-oxyde d'éthylène. L'un des points important de cette étude est l'ancrage de la phase organique sur le support inorganique. Deux agents de couplage : le propyl phosphonique acide 2-bromo-2-méthyl propanoate et le 3--propylamino triéthoxy silan ont été sélectionnés et greffés sur trois surface de TiO2 différentes : des nanoparticules, des surfaces denses et des surfaces poreuses. Pour chacune des deux molécules d'ancrage les meilleurs résultats ont été obtenus avec les nanoparticules. Les nanoparticules de TiO2 ainsi fonctionnalisées, ont dans une seconde étape, servi de semences pour l'élaboration de particules coeur-écorce. Deux voies de polymérisation ont été explorées avec succès : la si-ATRP et la si-ROMP. Dans le premier cas des greffons de poly-poly-éthylène glycol méthyl éther méthacrylate ont été introduits sur les nanoparticules de TiO2. Pour la si-ROMP les greffons incorporés sont à base de polynorbonène. Les résultats obtenus sur les nanoparticules de TiO2 ont été exploités afin de créer des couches polymères sur des supports poreux céramiques tubulaires commerciaux. Deux modes de conception ont été développés : la voie dite "coating onto" et celle dite "Grafting from". Les membranes composites obtenues par ces deux voies ont été testées en perméabilité des gaz afin de déterminer la qualité des couches polymères. Des essais préliminaires de séparation des gaz ont été également effectués. / This thesis work aims towards designing hybrid membranes for CO2 separation in the post-combustion process. The different methods of existing technologies are compared ans assessed for their merit, and the decision of using inorganic titanium dioxide supports integrated with a grown polymeric/PEG layer is made. First, the structure of the interfacing group is determined and narrowed down to phosphonic-based anchoring groups. The modification of various titanium oxide surfaces (i.e. particle, flat and porous) is performed with each group, and particles were found to yield the highest surface modification. Secondly, the functionalized particles of titania were then studied for their potential with si-ATRP and si-ROMP. in the case of phosphonic acid functionalized titania, the particles yielded a bromine terminus that could be used for si-ATPR. In the case of the silane grafted titania particles, further fonctionalization was required to ultimately yield a norbornenyl group that can be used for Si-ROMP. Both teechniques were shown to work, and were thus applied to longer ceramic tubes. Finally the development of two pathways ("Coating onto" and "Grafting from") were assessed for their ability to modify the tubular ceramic support and preliminary gas separation tests were performed. Phosphonique acide Silane Poly-éthylène glycol Poly-oxyde d'éthylène Si-ATRP Si-ROMP Membrane hybride Phosphonic acid Silane Polyethylene glycol Polyethylene oxide Si-ATRP Si-ROMP Hybrid membrane Coating onto Grafting from

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