Tailoring Structure and Function of Imidazole-Containing Block Copolymers for Emerging Applications from Gene Delivery to Electromechanical Devices

Green, Matthew Dale

06 December 2011

The imidazole ring offers great potential for a variety of applications including gene delivery vectors, ionic liquids, electromechanical actuators, and novel monomers and polymers. The imidazole ring provides a unique building block for these applications due to its thermal stability, aromatic nature, ability to form ionic salts, and ease of functionalization. Free radical polymerization of 1-vinylimidazole (1-VIm) and free radical copolymerizations with methyl methacrylate (MMA) and n-butyl acrylate (nBA) afforded homopolymers and copolymers with tunable solution and thermal properties. Aqueous SEC provided reproducible and reliable molecular weights for poly(1-VIm) in the absence of polymer aggregates. Analysis of the thermal properties revealed ideal random copolymers with MMA and non-ideal copolymers with nBA. Small angle X-ray scattering determined that the spacing between ionic groups remained constant with increased nonionic comonomer incorporation while the spacing between adjacent polymer backbones increased. Functionalization of 1-VIm with varying length alkyl halides and polymerization prepared a series of imidazolium homopolymers. Anion exchange reactions controlled the thermal and solution properties, and the bromide counteranion quantitatively exchanged to tetrafluoroborate (BF4), trifluoromethanesulfonate (TfO), and bis(trifluoromethanesulfonyl)imide (Tf2N). Thermogravimetric analysis revealed that thermal stability increased with decreased alkyl substituent length and larger counteranion size, and differential scanning calorimetry determined that glass transition temperature (Tg) decreased with increased alkyl substituent length and larger counteranion size. Electrochemical impedance spectroscopy determined the ionic conductivities of the imidazolium homopolymers, and analysis using the Vogel-Fulcher-Tammann equation revealed that the activation energy of ion conduction increased as alkyl substituent length increased. Polymer morphology determined using X-ray scattering also influenced the ionic conductivity. As the alkyl substituent length increased, the spacing between adjacent polymer backbones increased, which decreased the ionic conductivity due to the ion-hopping mechanism of ion conduction. Unsuccessful attempts to control the radical polymerization of 1-VIm led to the investigation of 1-(4-vinylbenzyl)imidazole (VBIm), which is a styrenic-based monomer with excellent propagating radical stability. Triblock copolymers incorporating VBIm monomer into a soft random copolymer center block and reinforcing, hard segment outer blocks provided a template for tuning the properties of the ionomer membranes for electroactive devices. Analysis of the morphology and mechanical properties using small angle X-ray scattering and dynamic mechanical analysis determined microphase separation and optimal mechanical properties for electromechanical transducer fabrication. Testing electromechanical transducers revealed superior performance relative to the benchmark Nafion®. Optimization of triblock copolymer design criteria through varying the comonomer ratio of VBIm and nBA in the soft center block, quaternization reactions, and ionic liquid introduction influenced mechanical properties and ionic conductivity. Higher percentages of VBIm and quaternization of VBIm in the random central block increased Tg and ionic conductivity. IL selectively incorporated into the imidazole-containing phases with no leakage observed for ionic systems, reduced the center block Tg, and increased ionic conductivity. Controlling charge density along poly(1-VIm) through well-defined alkylation reactions with 1-bromobutane provided a potential vector for nonviral gene delivery and polyanion binding. Analysis of DNA and heparin binding using gel electrophoresis revealed a decrease in N/P ratio with increased alkylation percentage. Dynamic light scattering indicated an increase in zeta potential with increasing alkylation percentages, and relatively uniform polyplex sizes in aqueous media. The MTT assay developed cytotoxicity profiles with little toxicity prior to 83% alkylation. Finally, the luciferase expression assay revealed inefficient nucleic acid delivery to multiple cell types. Synthesis of poly(1-VIm) vectors with glutathione conjugates provided an avenue for simultaneous therapeutic gene and anti-oxidant delivery in vitro. Cytotoxicity assays of cells pretreated with glutathione-conjugated poly(1-VIm) prior to oxidative stress showed that higher glutathione conjugation levels improved cell viability. / Ph. D.

imidazole

block copolymers

ionenes

nitroxide-mediated polymerization

gene delivery

ionic polymer transducers

ionic conductivity

Water ingression into poly(imide-siloxane)s

Kaltenecker-Commerçon, Joyce Marie, 1965-

06 June 2008

The interaction of water vapor with the surface and bulk of poly(imidesiloxane) copolymers has been characterized in an attempt to determine the important factors in the copolymer's resistance to water ingression. The multi-block copolymers were synthesized from benzophenone tetracarboxylic dianhydride, bisaniline P and pre-formed amine-terminated poly(dimethylsiloxane) oligomers, with phthalic anhydride as an end-capping agent. Similar copolymers had been previously shown to have reduced water sorption, increased surface hydrophobicity, and increased adhesive durability in hot/wet environments. Inverse gas chromatography was used to conduct surface energetics studies on copolymers of different siloxane concentration and a polyirnide homopolymer. Free energies of specific interaction of water vapor, ΔG_sp°, with the polymer surfaces were found to decrease with the incorporation of siloxane into the polyirnide. The dispersive components of the solid surface free energy of the siloxane- containing copolymers were equal within error to that of pure poly(dimethylsiloxane), indicating a PDMS-rich, hydrophobic surface. The ΔG_sp° of the copolymers were not significantly different, suggesting that the copolymer surfaces were very similar. This indicated a minimum weight percent of siloxane incorporation required to maximize the copolymer's surface water resistance. The minimum amount for the studied system was at most ten percent. Diffusion coefficients of water vapor in the polyimide and copolymers were determined from gravimetric sorption experiments. Higher levels of siloxane incorporation caused a definite increase in the diffusion coefficient, indicating a decreased resistance to water ingression. The increase in diffusion was found to be influenced by siloxane block length and was interpreted in terms of morphological and free volume theories. The diffusion coefficient of a 10 weight percent PDMS copolymer, however, was found to be the same within error as the polyimide diffusion oefficient. The incorporation of siloxane into polyimides has been shown to increase water resistance due to the hydrophobicity of the siloxane-rich surface. However, high siloxane contents also increased the rate of water ingression in the bulk of the polymer. Increased water resistance of the surface may be achieved at lower siloxane concentrations without increasing diffusive (or decreasing mechanical) properties to undesirable levels. / Ph. D.

LD5655.V856 1992.K358

Block copolymers

Polyimide siloxanes

Water vapor transport

Bridging Mesoscale Phenomena and Macroscopic Properties in Block Copolymers Containing Ionic Interactions and Hydrogen Bonding

Chen, Mingtao

08 August 2018

Anionic polymerization and controlled radical polymerization enabled the synthesis of novel block copolymers with non-covalent interactions (electrostatic interaction and/or hydrogen bonding) to examine the relationships between mesoscale phenomenon and macroscopic physical properties. Non-covalent interactions offer extra intra- and inter-molecular interactions to achieve stimuli-responsive materials in various applications, such as artificial muscles, thermoplastic elastomers, and reversible biomacromolecule binding. The relationship between non-covalent interaction promoted mesoscale phenomenon (such as morphology) and consequent macroscopic physical properties is the key to optimize material design and improve end-use performance for emerging applications. Pendant hydrogen bonding in ABA block copolymers promoted microphase separation and delayed the order-disorder transition, resulting in tunable morphologies (through composition changes) and extended rubbery plateaus. Reversible addition-fragmentation chain transfer (RAFT) polymerization afforded a facile synthesis of ABA triblock copolymers with hydrogen bonding (urea sites) and electrostatic interactions (pyridinium groups). Pyridine groups facilitated hydrogen bonding through a preorganization effect, leading to highly ordered, long-range lamellar morphology and a significant increase of flow temperature (Tf) 80 °C above the hard block Tg. After quaternization of pyridine groups, electrostatic interaction, as a second physical crosslinking mechanism, disrupted ordered lamellar morphology and decreased Tf. Yet, extra physical crosslinking from electrostatic interactions pertained ordered hydrogen bonding at high temperature and exhibited improved stress-relaxation properties. Both conventional free radical polymerization and RAFT polymerization generated a library of poly(ionic liquid) (PIL) homopolymers with imidazolium groups as bond charge moieties. A long chain alkyl spacer between imidazolium groups and the polymer backbones ensured a low glass transition temperature (Tg), which is beneficial to ion conductivity. Four different counter anions enabled readily tunable Tgs all below room temperature and showed promising ion conductivities as high as 2.45 × 10⁻⁵ S/cm at 30 °C. For the first time, the influence of counter anions on radical polymerization kinetics was observed and investigated thoroughly using in situ FTIR, NMR diffusometry, and simulation. Monomer diffusion and aggregation barely contributed to the kinetic differences, and the Marcus theory was applied to explain the polymerization kinetic differences which showed promising simulation results. RAFT polymerization readily prepared AB diblock, ABA triblock and (AB)3 3-arm diblock copolymers using the ionic liquid (IL) monomers discussed above and deuterated/hydrogenated styrene. We demonstrated the first example of in situ morphology studies during an actuation process, and counter anions with varied electrostatic interactions showed different mesoscale mechanisms, which accounted for macroscopic actuation. The long chain alkyl spacer between imidazolium groups and polymer backbones decoupled ion dynamics and structural relaxation. For the first time, composition changes of block copolymers achieved tunable viscoelastic properties without altering ion conductivity, which provided an ideal example for actuation materials, solid electrolytes, and ion exchange membranes. / Ph. D. / My research focuses on the synthesis of novel soft materials with a special interest in responsive polymers. The incorporation of responsive chemistry, such as hydrogen bonding and ionic interactions, enables soft materials with complex responsive behavior were achieved. Polymers with ion pairs promise great potential as solid-state electrolytes (which transfer ions to generate current) to eliminate potential fire hazard in batteries, which has been an arising concern for modern cellphone and electric car industry. The introduction of strong dipoles into polymers allows the fabrication of actuators, which convert electric signals to physical movement. Under applied voltage, polymers bend within seconds while holding physical loads. Actuator studies in polymers paves the way towards artificial muscles as well as soft robotics. Temperature responsive hydrogen bonding in polymers offers drastically different viscoelastic properties at different temperature and serves as the key mechanism in holt-melt adhesives, controlled drug release, and high performance materials.

poly(ionic liquid)s

electrostatic interactions

block copolymers

hydrogen bonding

RAFT polymerization

anionic polymerization

The effects of evaporation rate, solvent, and substrate on the surface segregation of block copolymers

Lawson, Glenn E.

04 March 2009

The surface chemistry of two systems of block copolymers was studied using angular dependent X-ray Photoelectron Spectroscopy poly(dimethyl (XPS). Surface concentration siloxane-b-sulfone)/polysulfone profiles of [PDMS/PSF] blends cast at several rates of solvent evaporation, and cast on several substrates were measured. Surface concentration profiles of poly(styrene-butadiene-styrene) poly(styrene-isoprene-styrene) [SIS] triblock [SBS] and copolymers cast at several rates of solvent evaporation, and cast from two different solvents were also measured. The concentration profile analyses were made using three different XPS quantification techniques. The PDMS/PSF systems were analyzed using the peak area ratio, and the SBS and SIS copolymers were analyzed using both the Cls shakeup to main ratio, and spectral measurements of the valence band. The results of this study indicate a variation in surface concentration as well as concentration gradient for different sample preparation routes. The variations can be explained by considering the rate of film formation (kinetics), polymer - solvent interactions, and polymer - substrate interactions. However, in both systems the lower surface energy copolymer block (siloxane block, or diene block) preferentially segregated to the surface for all of the sample preparation routes stUdied. / Master of Science

LD5655.V855 1985.L387

Block copolymers -- Surfaces

Surface chemistry

Surfaces (Technology) -- Analysis

Self-organized nanoporous materials for chemical separations and chemical sensing

Pandey, Bipin

January 1900

Doctor of Philosophy / Department of Chemistry / Takashi Ito / Self-organized nanoporous materials have drawn a lot of attention because the uniform, highly dense, and ordered cylindrical nanopores in these materials provide a unique platform for chemical separations and chemical sensing applications. Here, we explore self-organized nanopores of PS-b-PMMA diblock copolymer thin films and anodic gallium oxide for chemical separations and sensing applications. In the first study, cyclic voltammograms of cytochrome c on recessed nanodisk-array electrodes (RNEs) based on nanoporous films (11, 14 or 24 nm in average pore diameter; 30 nm thick) derived from polystyrene-poly(methylmethacrylate) diblock copolymers were measured. The faradic current of cytochrome c was observed on RNEs, indicating the penetration of cytochrome c (hydrodynamic diameter ≈ 4 nm) through the nanopores to the underlying electrodes. Compared to the 24-nm pores, the diffusion of cytochrome c molecules through the 11- and 14-nm pores suffered significantly larger hindrance. The results reported in this study will provide guidance in designing RNEs for size-based chemical sensing and also for controlled immobilization of biomolecules within nanoporous media for biosensors and bioreactors. In another study, conditions for the formation of self-organized nanopores of a metal oxide film were investigated. Self-organized nanopores aligned perpendicular to the film surface were obtained upon anodization of gallium films in ice-cooled 4 and 6 M aqueous H2SO4 at 10 V and 15 V. The average pore diameter was in the range of 18 ~ 40 nm, and the anodic gallium oxide was ca. 2 µm thick. In addition, anodic formation of self-organized nanopores was demonstrated for a solid gallium monolith incorporated at the end of a glass capillary. Nanoporous anodic oxide monoliths formed from a fusible metal will lead to future development of unique devices for chemical sensing and catalysis. In the final study, surface chemical property of self-organized nanoporous anodic gallium oxide is explored through potentiometric measurements. The nanoporous anodic and barrier layer gallium oxide structures showed slow potentiometric response only at acidic pH (≤ 4), in contrast to metallic gallium substrates that exhibited a positive potentiometric response to H⁺ over the pH range examined (3-10). The potentiometric response at acidic pH probably reflects some chemical processes between gallium oxide and HCl.

Self-organized nanoporous materials

Block copolymers

Diffusion of cytochrome

Finite element simulation

COMSOL multiphysics

Anodic gallium oxide

Chemistry (0485)

N-vinylpyrrolidone-vinyl acetate block copolymers as drug delivery vehicles

Bailly, Nathalie

03 1900

Thesis (PhD)--Stellenbosch University, 2012. / ENGLISH ABSTRACT: The primary aim of this study was to investigate the feasibility of the amphiphilic block copolymer poly((vinylpyrrolidone)-b-poly(vinyl acetate)) (PVP-b-PVAc) as a vehicle for hydrophobic anti-cancer drugs. PVP-b-PVAc block copolymers of constant hydrophilic PVP block length and varying hydrophobic PVAc block lengths were synthesized via xanthate-mediated controlled radical polymerization (CRP). The methodology consisted of growing the PVAc chain from a xanthate end-functional PVP. In an aqueous environment the amphiphilic block copolymers selfassembled into spherical vesicle-like structures consisting of a hydrophobic PVAc bilayer membrane, a hydrophilic PVP corona and an aqueous core. The self-assembly behaviour and the physicochemical properties of the self-assembled structures were investigated by 1H NMR spectroscopy, fluorescence spectroscopy, transmission electron microscopy (TEM) and dynamic and static light scattering. Drug loading studies were performed using a model hydrophobic drug, clofazimine, and a common anti-cancer drug paclitaxel (PTX) to evaluate the potential of the PVP-b-PVAc block copolymers for drug delivery,. Clofazimine and PTX were physically entrapped into the hydrophobic domain of the self-assembled PVP-b-PVAc block copolymers via the dialysis method. The drug-loaded PVP-b-PVAc block copolymers were characterized regarding particle size, morphology, stability and drug loading capacity in order to assess their feasibility as a drug vehicle. The polymer vesicles had a relatively high drug loading capacity of 20 wt %. The effect of the hydrophobic PVAc block length on the drug loading capacity and encapsulation efficiency were also studied. Drug loading increased with increasing the hydrophobic PVAc block length. The effect of the drug feed ratio of clofazimine and PTX on the drug loading capacity and encapsulation efficiency were also investigated. The optimal formulation for the drug-loaded PVP-b-PVAc was determined and further investigated in vitro. The size stability of the drugloaded PVP-b-PVAc block copolymers was also assessed under physiological conditions (PBS, pH 7.4, 37 °C) and were stable in the absence and presence of serum. PVP-b-PVAc block copolymers were tested in vitro on MDA-MB-231 multi-drug-resistant human breast epithelial cancer cells and normal MCF12A breast epithelial cells to provide evidence of their antitumor efficacy. In vitro cell culture studies revealed that the PVP-b-PVAc drug carrier exhibited no cytotoxicity towards MDA-MB-231 and MCF12A cells, confirming the biocompatibility of the PVP-b-PVAc carrier. In vitro cytotoxicity assays using clofazimine-PVPb- PVAc formulations showed that when MDA-MB-231 cells were exposed to the formulations, an enhanced therapeutic effect was observed compared to the free drug. Cellular internalization of the PVP-b-PVAc drug carrier was demonstrated by fluorescent labeling of the PVP-b-PVAc carrier. Fluorescence microscopy results showed that the carrier was internalized by the MDAMB- 231 cells after 3 hours and localized in the cytoplasm and the perinuclear region. Overall, it was demonstrated that PVP-b-PVAc block copolymers appear to be promising candidates for the delivery of hydrophobic anti-cancer drugs. / AFRIKAANSE OPSOMMING: Die studie is gebaseer op die gebruik van amfifieliese blokkopolimere van poli((Nvinielpirolidoon)- b-poli(vinielasetaat)) (PVP-b-PVAc) as potensiële geneesmiddeldraers. PVP-b-PVAc blokkopolimere van konstante hydrofiliese bloklengte en verskillende hydrofobiese bloklengte is voorberei via die RAFT/MADIX-proses. Blokkopolimere met vinielasetaat is vanaf poli(N-vinielpirolidoon) met ‘n xantaatendfunksie voorberei. In ‘n wateromgewing vorm die PVP-b-PVAc blokkopolimere vesikel strukture met ‘n hydrofobiese membraan en ‘n hydrofiliese mantel. Die fisies-chemiese eienskappe van die PVP-b-PVAc blokkopolimere is gekarakteriseerd met gebruik van KMR spektroskopie, fluoresent spektroskopie, transmissie elektronmikroskopie (TEM) en dinamiese en statiese lig verstrooiing. Die potensiaal van PVP-b-PVAc as ‘n geneesmiddeldraer is ondersoek deur gebruik te maak van die hydrofobiese geneesmiddel, clofazimine, en ‘n anti-kanker geneesmiddel, paclitaxel. Clofazimine en paclitaxel is ge-inkapsuleer in die hydrofobiese gedeelte van die blokkopolimere via die dialise-metode. Clofazimine-PVP-b-PVAc en paclitaxel-PVPb- PVAc blokkopolimere is gekarakteriseerd met betrekking tot die partikel grootte, morfologie, stabiliteit en laai kapasitiet om die PVP-b-PVAc blokkopolimere as geneesmiddeldraers te evalueer. Die PVP-b-PVAc geneesmiddeldraer het ‘n relatiewe hoë laai kapsiteit van 20 gew % aangetoon. Die invloed van die bloklengte op die laai kapasitiet is ook ondersoek en beskryf. ‘n Toename in die laai kapasitiet is gesien met ‘n toename in die hydrofobiese bloklengte. Die invloed van die hoeveelheid geneesmiddel op die laai kapasitiet en die inkapsuleer doeltreffendheid is ook ondersoek. Die optimale formulasie is gevind en verder gebruik vir in vitro studies. Die stabiliteit van die geneesmiddeldraer in fisiologiese omstandighede (pH 7.4, 37 °C) is ook beskryf. Resultate toon aan dat die sisteem stabiel is onder hierdie omstandighede in die afwesigheid en aanwesigheid van serum. In vitro eksperimente is op MCF12A epiteel-borsselle en MDA-MB-231 epiteelborskankerselle getoets om die anti-tumoraktiwiteit te ondersoek. Resultate toon aan dat die PVP-b-PVAc geen sitotoxiese effek op die selle het nie, wat aandui dat die polimere bioverenigbaar is. Verder is dit bewys dat die PVP-b-PVAc geneesmiddel formualsie ’n hoër sitotoxisiteit besit as die vry-geneesmiddel. Fluoresent studies het aangetoon dat die geneesmiddeldraer na 3 uur opgeneen word deur MDA-MB231 selle en gelokaliseerd is in die sitoplasma en in die omgewing van die kern van die selle. In die algemeen is dit aangetoon dat PVP-b-PVAc blokkopolimere potensiële kandidate vir die lewering van hydrofobiese geneesmiddels is.

Block copolymers

Polymeric drug delivery systems

Polymers in medicine

Dissertations -- Polymer science

Theses -- Polymer science

Chemistry and Polymer Science

Thermal field-flow fractionation (Thermal FFF) and asymmetrical flow field-flow fractionation (AF4) as new tools for the analysis of block copolymers and their respective homopolymers

Ngaza, Nyashadzashe

12 1900

Thesis (MSc)--Stellenbosch University, 2014. / ENGLISH ABSTRACT: Polystyrene-block-poly(ethylene oxide) (PS-b-PEO) copolymers contain a hydrophilic PEO block and a hydrophobic PS block. PS and PEO have different affinities for most organic solvents and as a result, the PS-b-PEO copolymers are difficult to characterize in solution. In order to achieve a complete characterization of their molecular heterogeneity different techniques have been used. Recently FFF has become a cutting edge technology for polymer analysis because it possesses a number of advantages over conventional SEC and other liquid chromatographic techniques. The mild operating conditions allow the analysis of delicate and sensitive complex analytes such as complex polymer assemblies. The ability to analyze polymers with ultrahigh molar masses has also contributed to its significance in the characterization of polymers. In this study, the FFF behaviour of PS-b-PEO copolymers as well as PS and PEO homopolymers was investigated using Thermal FFF in different organic solvents and AF4. The aim of the study was the correlation of the thermodynamic quality of the solvents and the elution behaviour of the polymers. Unfortunately, PEO homopolymers have been found to interact with the membrane in AF4. Therefore, they were best characterized in organic solvents using Thermal FFF. In contrast to AF4 no specific interactions occurred due to the absence of a membrane. Results for Thermal FFF showed that in all utilized solvents, PS and PEO homopolymers were separated in the direction of increasing molar mass. For PS-b-PEO copolymers the retention in selective (good) solvents for PS was dependent on the molar mass of the PS block in the block copolymer. This was explained by the fact that in poor solvents PEO adopts a collapsed coil conformation while PS is present in extended random coil conformation. Results also showed that polymer retention was dependent on the temperature programme utilized. The fractionations by Thermal FFF indicated that some of the PS-b-PEO copolymer samples contained PS and PEO homopolymers as by-products. After semi-preparative fractionation these homopolymers were qualitatively identified using FTIR spectroscopy. / AFRIKAANSE OPSOMMING: Polistireen-blok-poli(etileenoksied) (PS-b-PEO) ko-polimere bevat 'n hidrofiliese politetileen oksied (PEO) blok en 'n hidrofobiese polistireen (PS) blok. PS en PEO het verskillende affiniteite vir die meeste organiese oplosmiddels, dit bemoeilik die karakterisering van PS-b-PEO ko-polimere in oplossing. Ten einde 'n volledige karakterisering van hul molekulêre heterogeniteit te bepaal moet ‘n verskeidenheid van tegnieke gebruik word. Onlangs het veldvloeifraksionering (FFF) baie grond gewen tov polimeer analise, aangesien dit verskeie voordele het bo tradisionele chromatografiese tegnieke soos grootte-uitsluitingschromatografie (SEC). Die ligte operasionele omstandighede laat die ontleding van ‘n verskeidenheid van polimere toe, enige iets van delikate polimeer komplekse tot ultra hoë molekulêre massa. In hierdie studie is die FFF gedrag van PS-b-PEO ko-polimere asook PS en PEO homopolimere ondersoek met behulp van Termiese FFF(ThFFF) in verskillende organiese oplosmiddels en onsimmetriese vloei-veldvloeifraksionering(AF4). Die doel van die studie was om die verband tussen die termodinamiese gehalte van die oplosmiddels en die eluering gedrag van die polimere te bepaal. Analise van PEO homopolimere was onsuksesvol aangesien daar interaksie was met die membraan. PEO is dus net geanaliseer in organise oplosmiddels met behulp van ThFFF, aangesien daar geen membraan is nie. Analise met ThFFF het gewys dat skeiding plaasvind volgens ‘n toename in molekulêre massa in organise oplosmiddels. Vir PS-b-PEO ko-polimere die retensie in selektiewe (goeie) oplosmiddels vir PS was afhanklik van die molekulêre massa van die PS blok in die ko-polimeer. ‘n Moontlike teorie is dat die PEO blok ‘n ineengestorte spoel struktuur vorm terwyl die PS blok ‘n uitgestrekte lukraake vorm aan neem. Resultate het ook getoon dat die polimeer retensie afhanklik was van die temperatuur program wat gebruik is. Die fraksionering deur ThFFF het aangedui dat sommige van die PS-b-PEO kopolimeer monsters bestaan het uit PS en PEO homopolimere as by-produkte. Hierdie is kwalitatief bewys deur analise van die fraksies na fraksionering van die ko-polimere met behulp van FTIR spektroskopie.

Field-flow fractionation

Thermal diffusion

Polymers -- Thermal properties

Block copolymers -- Analysis

Dissertations -- Polymer science

Theses -- Polymer science

UCTD

Polymères nanostructurés à base de nanotubes de carbone

Semaan, Chantal

20 December 2010

Ce travail de thèse concerne l’étude de dispersions de nanotubes de carbone (NTC) dans une matrice polymère afin d’obtenir des matériaux nanocomposites avec des propriétés améliorées. Dans la première partie, nous nous sommes intéressés à l’enrobage des NTC par des copolymères à blocs amphiphiles afin de faciliter la dispersion en solution aqueuse. L’influence de la structure chimique, de la composition et de la masse molaire des copolymères sur les propriétés a été étudiée. Dans une deuxième partie, l’incorporation des NTC dans une matrice polymère a été développée. Des procédés par voie aqueuse et par voie fondue ont été choisis afin de contrôler la répartition des NTC dans une matrice modèle de polyoxyde d’éthylène ainsi que dans des de polyéthylène ou de polyméthacrylate de méthyle. L’étude des propriétés physiques, notamment rhéologiques et électriques des nanocomposites à renfort de nanotubes a été réalisée. Ainsi les relations entre l’état des dispersions, la nature de l’enrobage et le mode d’élaboration des composites ont été établies. / This work is concerned with the study of carbon nanotubes (CNT) dispersions in a polymer matrix in order to obtain nanocomposite with unique properties. In the first part, we investigated the CNT wrapping by amphiphilic block copolymers to facilitate their suspension in aqueous solution. Based on the results, we could assess the effect on CNT dispersion quality of the molar mass of copolymers, the nature of the hydrophobic block and the length of hydrophilic block. In the second part, the incorporation of CNTs in polymer matrix was developed. Water or melt processing were chosen to control the distribution of CNTs in various polymer matrices (Polyethylene oxide, polyethylene and polymethyl methacrylate) through a prior wrapping of CNT. The studies of physical properties, including rheological and electrical properties, of nanocomposites were undertaken. Relationships between the state of dispersion, the nature of the coating and the method of preparation of composites were established.

Nanotubes de carbone

Copolymères amphiphiles

Nanocomposite

Percolation électrique

Percolation rhéologique

Carbon nanotubes

Amphiphilic block copolymers

Nanocomposites

Electrical percolation

Rheological percolation

Improvement of compatibility of poly(lactic acid) blended with natural rubber by modified natural rubber / Amélioration de la compatibilité de l'acide polylactique mélangé au caoutchouc naturel par des dérivés du caoutchouc naturel

Chumeka, Wannapa

11 December 2013

L’objectif de ce travail de thèse était l’amélioration de la compatibilité de mélanges d’acide polylactique et de caoutchouc naturel (mélanges PLA/NR) par l’ajout de dérivés du caoutchouc naturel comme agents compatibilisants. Le caoutchouc naturel a été modifié selon deux approches : synthèse d’un copolymère greffé caoutchouc- poly(vinyl acétate) (NR-g-PVAc) et synthèse de polymères à blocks PLA-NR et PLA-NR-PLA. Les mélanges PLA/NR ont été préparés par extrusion dans une extrudeuse à double vis et moulées par compression pour obtenir des feuilles de 2 mm d’épaisseur. Les mélanges contenaient 10-20% en poids de NR et NR modifiée. La résistance au choc et les propriétés en traction ont été étudiées. L’effet de compatibilisation a été déterminé par DMTA, DSC et MEB. NR-g-PVAc a été synthétisé par polymérisation en émulsion pour obtenir de copolymères avec différents contenus en PVAc greffé (1%, 5% and 12%). La caractérisation des matériaux par DMTA a montré une augmentation de la miscibilité des mélanges PLA/NR-g-PVAc.NR-g-PVAc a résulté être un agent durcissant pour le PLA et un agent compatibilisant pour les mélanges PLA/NR. Les polymères à bloc ont été synthétisés selon deux routes : (1) NR hydroxy téléquelique (HTNR) et lactide et (2) NR hydroxy téléquelique et pré-polymère PLA. Dans la première approche, le lactide a été polymérisé in situ à travers la polymérisation par ouverture de cycle pour donner un bloc. Dans la deuxième approche, le pré-polymère PLA a été synthétisé par polymérisation directe de l’acide L-lactique avant copolymérisation à blocs. Les deux types de copolymères se sont révélés de bons agents compatibilisants pour les mélanges PLA/NR, car ils ont augmenté la résistance au choc et ils ont diminué la taille des particules de caoutchouc. / The aim of this research work was to improve the compatibility of polymer blends made from poly(lactic acid) and natural rubber (PLA/NR blends) by using modified natural rubber as a compatibilizer. Natural rubber was chemically modified into two categories: natural rubber grafted poly(vinyl acetate) copolymer (NR-g-PVAc) and block copolymers (PLA-NR diblock copolymer and PLA-NR-PLA triblock copolymer). PLA/NR blends were prepared by melting blending in a twin screw extruder and compression molded to obtain a 2-mm thick sheet. The blends contained 10-20 wt% of NR and modified NR, and the impact strength and tensile properties were investigated. The compatibilization effect was determined by DMTA, DSC and SEM. NR-g-PVAc was synthesized by emulsion polymerization to obtain different PVAc graft contents (1%, 5% and 12%). Characterization by DMTA showed an enhancement in miscibility of the PLA/NR-g-PVAc blends. NR-g-PVAc could be used as a toughening agent of PLA and as a compatibilizer of the PLA/NR blend. The block copolymers were synthesized following two routes: (1) hydroxyl telechelic natural rubber (HTNR) and lactide and (2) HTNR and PLA prepolymer. In the former route, lactide was in situ polymerized via a ring opening polymerization to be a PLA block segment during block copolymerization. In the latter route PLA prepolymer was synthesized by a condensation polymerization of L-lactic acid prior to block copolymerization. Both block copolymers acted as good compatibilizers for the PLA/NR blend by increasing the impact strength and decreasing the NR particle size. Triblock copolymers provided higher impact strength than diblock copolymers, and they were a less effective compatibilizer than NR-g-PVAc. In contrast to NR and NR-g-PVAc, the block copolymer was not a good toughening agent for PLA.

Polymères biobasés

Acide polylactique

Caoutchouc naturel

Copolymères à block / greffés

Biobased polymers

Polylactic acid

Natural rubber

Graft / block copolymers

547.842 6

Synthèse, caractérisation, étude des performances de polymères à blocs utilisés comme liants de peintures anti-salissures marines / Synthesis, characterization, performances of block copolymers as binders for marine antifouling paints

Duong, The-Hy

27 May 2014

L’objectif de ces travaux est de synthétiser des copolymères diblocs et triblocs à base d'unités monomères méthacrylate de tert-butyldiméthylsilyle et diméthylsiloxane. Le choix de ces unités monomères repose sur l'élaboration de films polymères hydrolysables dans le milieu marin et de faible énergie libre de surface, respectivement. Ces polymères ont été caractérisés puis utilisés comme liants dans la formulation de peintures anti-salissures marines SPC/FRC hybrides. Les performances des revêtements obtenus ont alors été comparées aux deux types de revêtements anti-salissures marines disponibles sur le marché : - les revêtements auto-polissants (Self-polishing copolymer, SPC), à base de liants polymères hydrolysables, efficaces par relargage de biocides dans le milieu marin et par érosion, mais toxiques pour l’environnement ; - les revêtements Fouling Release" (FRC), hydrophobes à base de silicone, et non toxiques, qui limitent la force d’adhésion des salissures mais sans efficacité en mode statique.Le procédé de polymérisation RAFT a été employé afin de synthétiser des polymères avec des architectures, des compositions et des masses molaires contrôlées. Des macro-agents de transfert de chaîne à base de poly(diméthylsiloxane)s ont été préalablement synthétisés à partir de poly(diméthylsiloxane)s mono et di-hydroxylés, de masses molaires 1000 , 5000 et 10000 g.mol-1. Trois séries de copolymères ont été préparées avec des masses molaires allant de 12000 à 60000 g.mol-1 et des teneurs en unités diméthylsiloxanes allant de 3% à 57%.Les propriétés de prise en eau, d'érosion (type SPC) et de mouillabilité (type FRC) ont été étudiées pour les liants seuls et les revêtements formulés avec et sans biocides. L'évolution de l'hydrophobie de surface des revêtements pendant leur immersion en eau de mer artificielle a été suivie. L'efficacité anti-adhésion bactérienne d'une série de copolymères, sous forme de vernis et de revêtements formulés, a été étudiée vis-à-vis de deux souches de bactéries marines. Enfin, l’efficacité anti-salissure marine des vernis et des revêtements formulés avec et sans biocides a été évaluée lors d'une immersion in-situ en Mer Méditerranée pendant 16 mois au maximum. / The aim of this study is to synthesize diblock and triblock copolymers based on tert-butyldimethylsilyl methacrylate and dimethylsiloxane monomer units. These monomer units have been selected to elaborate polymer films both hydrolysable in the marine environment and with a low surface energy. These copolymers have been fully characterized and have been formulated to develop FRC/SPC hybrid antifouling coatings. The performances of these new coatings have been compared to the two main types of antifouling coatings on the market:- the Self-Polishing coatings (SPC), based on hydrolysable polymer binders with an efficiency relied on the release of biocides in the marine environment and the erosion of the coating. Unfortunately, these coatings toxic for the marine environment;- the Fouling Release Coatings (FRC), based on hydrophobic and non-toxic silicone-based coatings which limit the adhesion strength of fouling organisms. Nevertheless, they are not efficient during idle periods. Block copolymers with controlled architecture, chemical composition and molar masses have been synthesized via the RAFT process from poly(dimethylsiloxane)-based chain transfer agents. These macro-chain transfer agents have been previously prepared from mono- and di-hydroxylated poly(dimethylsiloxane)s with molar masses of 1,000, 5,000 and 10,000 g.mol-1. Three series of copolymer have been synthesized with molar masses ranging from 12,000 to 60,000 g.mol-1 and a mass content of dimethylsiloxane units ranging from 3% to 57%. The water uptake, the erosion properties (SPC type) and the hydrophobicity (FRC-type) have been studied for both the binders and the coatings formulated with and without biocides. The evolution of the hydrophobic properties of the coatings' surface has been investigated during their immersion in artificial seawater. The anti-adhesion properties of one series of copolymers have been investigated toward two marine bacterial strains. Then, the antifouling efficiency of the binders and the coatings formulated with and without biocides has been evaluated during their in-situ immersion in the Mediterranean Sea for 16 months at a maximum.

Polymères à bloc

Polymérisation RAFT

Block copolymers

RAFT polymerisation

FRC/SPC hybrid antifouling coatings