Kinetics and Mechanism of Cu-Catalyzed Atom Transfer Radical Polymerization

Sörensen, Nicolai

26 May 2015

No description available.

540

copper

deactivation

termination

chain-length dependence

electron paramagnetic resonance (EPR)

kinetics

spectroscopy

pulsed-laser polymerization (PLP)

Chemie  (PPN62138352X)

Azlactome funchionalization of magnetic nanoparticles using CRP techniques and their bioconjugation / Fonctionnalisation de nanoparticules magnétiques par des groupements azlactone à l’aide de techniques de polymérisation radicalaire contrôlée et application à la bioconjugaison

Pray-In, Yingrak

24 March 2014

Ce travail concerne la modification de surface de nanoparticules magnétiques (MNP) par des copolymères réactifs renfermant des cycles azlactone, aux fins de l’élaboration de nano-supports destinés à l’immobilisation de biomolécules. Trois stratégies basées sur des techniques de polymérisation radicalaire contrôlée ont été mises en œuvre.Dans la première, un copolymère poly(méthacrylate de poly(éthylène glycol)-stat-2-vinyl-4,4-diméthylazlactone) (poly(PEGMA-stat-VDM)) a été préparé par polymérisation radicalaire par transfert d’atome (ATRP) selon la technique « grafting from » à partir des MNP et utilisé pour la bioconjugaison de thymine peptide nucleic acid (PNA). La présence de l’écorce polymère et l’immobilisation du PNA ont été confirmées par différentes techniques complémentaires (FTIR, VSM).La deuxième stratégie est basée sur l’élaboration de MNP greffées pour la bioconjugaison de l’acide folique, via l’ARTP du PEGMA et de la VDM. L’analyse par microscopie électronique à transmission (TEM) a montré qu’après bioconjugaison les MNP possèdent une très bonne aptitude à la dispersion en milieu aqueux.La troisième stratégie met en œuvre la technique «grafting onto » de copolymères poly(oxyde d’éthylène)-bloc-poly(2-vinyl-4,4-dimethylazlactone) (PEO-b-PVDM) pour la préparation de nanosupports magnétiques recyclables. Des copolymères à blocs PEO-b-PVDM ont été préparés par la technique de polymérisation RAFT puis greffés sur des MNP fonctionnalisées amino-silane. Les analyses en TEM et par spectroscopie de corrélation de photons ont révélé l’aptitude à la dispersion aqueuse et à la formation de nanoclusters. Les clusters ainsi obtenus ont été utilisés en tant que nanosupports magnétiques recyclables pour l’adsorption d’anticorps. / We herein report the surface modification of magnetite nanoparticle (MNP) with copolymers containing active azlactone rings via a grafting ‘from’ and grafting ‘onto’ controlled radical polymerization (CRP) for use as a nano-solid support for immobilization with biomolecules. Three different approaches were presented as following. First, synthesis of poly(poly(ethylene glycol) methyl ether methacrylate-stat-2-vinyl-4,4-dimethylazlactone) (PEGMA-stat-VDM)-grafted MNP via a grafting ‘from’ atom transfer radical polymerization (ATRP) and its application as a platform for conjugating thymine peptide nucleic acid (PNA) monomer were presented. The presence of polymeric shell and the immobilization of thymine PNA on MNP core were confirmed by fourier transform infrared spectroscopy (FTIR) and vibrating sample magnetometry (VSM) techniques. The second strategy is based on the synthesis of MNP grafted with PEGMA and VDM via ATRP for conjugation with folic acid (FA). The existence of PEGMA and VDM in the structure was characterized by FTIR, TGA and VSM. After the FA conjugation, Transmission Electron Microscopy (TEM) results indicated that the FA-conjugated MNP having high VDM content exhibited good dispersibility in water.Third, the synthesis of MNP grafted with poly(ethylene oxide)-block-poly(2-vinyl-4,4-dimethylazlactone) (PEO-b-PVDM) block copolymer via a grafting ‘onto’ strategy and its application as recyclable magnetic nano-support for adsorption with antibody were studied. PEO-b-PVDM diblock copolymers were first synthesized using reversible addition-fragmentation chain transfer (RAFT) polymerization and then grafted onto amino-functionalized MNP. TEM images and photo correlation spectroscopy (PCS) indicated an improvement in the particle dispersibility in water after coating with the copolymers. The nanoclusters with PEO-b-PVDM copolymer coating were used as recyclable magnetic nano-supports for adsorption with antibody.

Nanoparticules magnétiques

Copolymère à blocs

Greffage

Polymérisation radicalaire contrôlée

RAFT

ATRP

Bioconjugaison

Azlactone

Magnetic nanoparticles

Diblock copolymers

Grafting

Controlled radical polymerization

Atom transfer radical polymerization

668.92

Modeling of solution and surface–initiated atom transfer radical polymerization

Mastan, Erlita

01 December 2015

Controlled radical polymerization (CRP) can be viewed as the middle ground between living anionic polymerization (LAP) and conventional free radical polymerization (FRP). It combines the precise control over polymer structure offered by LAP, under a tolerant reaction condition similar to FRP. One of the most studied CRP is atom transfer radical polymerization (ATRP), with over 10,000 papers published since its introduction in 1995. Despite the numerous studies, knowledge on its fundamental mechanism is still lacking, as evident from the lack of expression for full MWD and polydispersity that account for termination reaction. Since termination is unavoidable in ATRP, the existing expressions give inaccurate predictions as dead chains accumulate. In this study, we derived expressions for full MWD at low conversion and for polydispersity. These expressions allow us to quantify and gain better understanding on the contribution of termination. In addition, the resulting polydispersity expression shows better agreement than the existing equation when correlated with experiment data. In addition to the aforementioned questions, there are also controversies regarding the kinetics of surface-initiated ATRP, with researchers divided into two schools of theories. We evaluated the validity of these theories by comparing their predictions to experimental trends. Both theories were found to be inadequate in explaining all the experimental observations, thus triggering an investigation of the graft density. Graft density is an important determining property for polymer brushes, yet little is known about what affects its final value. Through simulations, we investigated the effect of experiment factors on the grafting density. A decrease in the amount of deactivator is found to decrease the grafting density, which could be explained by an increase in the number of monomers added per activation cycle. This knowledge allows us to explain the conflicting experiment observations regarding the growth trends of polymer layers reported in the literatures. / Thesis / Doctor of Philosophy (PhD) / Polymer materials are used almost everywhere in our daily life from clothing to water bottle. This wide range of applications owes to the nearly infinite possible properties that polymer can possess. Different polymerization processes to synthesize polymers have their own weaknesses and strengths. Herein we investigated the fundamental mechanism of one of the currently most attractive polymerization systems, atom transfer radical polymerization (ATRP). This process allows the synthesis of polymers with precisely tailored chain microstructures, making it possible to create polymer with sophisticated properties. Using modeling approaches, we derived explicit expressions for determining chain properties, allowing detailed investigation of how various factors affect these properties. Through these investigations, we obtained better understanding on the mechanism of ATRP in solution and on surface. This knowledge is crucial in providing insight and guiding experimental designs for better control over the material properties.

Kinetic modeling

Monte Carlo simulation

Bond-fluctuation method

Surface-initiated polymerization

SI-ATRP

Graft polymerization

Molecular weight distribution

Chain length distribution

Polydispersity index

Dispersity

Radical termination

Controlled radical polymerization

Synthesis of AcGGM Polysaccharide Hydrogels

Maleki, Laleh

January 2016

Lignocellulosic biomass is believed to serve a prominent role in tomorrow’s sustainable energy and material development. Among the polysaccharide fractions of lignocellulosic biomass, the potential of hemicelluloses as a valuable material resource is increasingly recognized. Thanks to their hydrophilic structure, hemicelluloses are suitable substrates for hydrogel design. The work summarized in this thesis aims to develop feasible strategies for the conversion of O-acetyl galactoglucomannan (AcGGM), an ample hemicellulose in softwood, into hydrogels. Within this framework, four synthetic pathways targeting the formation of crosslinked hydrogel networks from pure or unrefined AcGGM fractions were developed.   Aqueous AcGGM-rich and lignin-containing side-stream process liquors of forest industry, known as softwood hydrolysates (SWHs) were formulated into highly swellable hydrogels by: i) allyl-functionalization of AcGGM chains of crude SWH to obtain a viable precursor for hydrogel synthesis via free-radical crosslinking, ii) directly incorporating unmodified SWH fractions into semi-interpenetrating polymer networks (semi-IPNs). SWH hydrogels and semi-IPNs were characterized with appreciable maximum swelling ratios of Qeq = 170 and Qeq = 225, respectively.   Rapid crosslinking of AcGGM through thiol-click chemistry was addressed by first imparting thiol functionality onto pure AcGGM chains in a one-pot procedure. The thiolated AcGGM proved to be a suitable substrate for the synthesis of hemicellulose hydrogels via thiol-ene and thiol Michael addition reactions. Finally, sequential full IPNs were developed by subjecting single network hydrogels of pure AcGGM to a second network formation. IPNs obtained through either free radical crosslinking or thiol-ene crosslinking exhibited higher shear storage moduli than their single network counterparts. / <p>QC 20161102</p>

hemicellulose

O-acetyl-galactoglucomannan

wood hydrolysate

hydrogel

radical polymerization

interpenetrating polymer network

click chemistry

thiol-ene

Michael addition

Elaboration de membranes polymères auto-réparables / Elaboration of self-healing polymer membranes

Tyagi, Prashant

23 November 2012

L'objectif de cette thèse est d'élaborer et de développer un type de membranes polymères qui peuvent se réparer de manière autonome en cas de fissures. Si elles ne sont pas détectées, ces fissures peuvent poser des problèmes notamment pour des applications médicales. Dans une première partie, une membrane polymère dynamique à base de micelles de copolymère tribloc ABA a été préparée. Le bloc "A" est représenté par le poly (styrene-co-acrylonitrile), copolymère bloc mécaniquement robuste, et un bloc "B" relativement mou et souple, le poly (ethylene oxide). Lorsqu'une pression est appliquée à la membrane, sa morphologie peut être ajustée grâce à la nature compressible des micelles, ainsi que les ponts dynamiques intermicellaires. Une gamme de porosités accessible peut être régulée par la pression et de manière à contrôler la performance de filtration. La même nature dynamique a également été utilisée pour montrer une réparation autonome entrainée par la pression. L'efficacité du processus de réparation dépend de la taille des fissures, de la valeur de pression et de la durée d'application de la pression. En utilisant la propriété d'auto-réparation de la membrane ci-dessus, le processus « Direct Mode Translocation » de nanoparticules a également été étudié. Quatre classes différentes de nanoparticules ont été utilisées avec diverses propriétés intrinsèques et extrinsèques. Les conclusions de ces travaux prouvent que les caractéristiques de taille, de forme et de surface des nanoparticules ainsi que la force exercée régissent le processus de translocation. Dans une seconde partie, un revêtement 2D et 3D réversible basé sur l'auto-assemblage de micelles de copolymère dibloc constitué d'un poly (methyl methacrylate) (PMMA) et du poly (n-octadecyl methacrylate) (PODMA) blocs a été développé. L'assemblage de micelles est réalisé par l'effet "Zipper", grâce aux longues chaînes pendantes du bloc PODMA. Le même effet "Zipper" permet d'enlever facilement le revêtement par lavage dans un solvant sélectif, donnant ainsi la possibilité de modifier la surface d'un substrat plusieurs fois de manière réversible. La cristallisation à température ambiante du bloc PODMA offre la possibilité d'avoir un revêtement auto-réparable thermiquement sans affecter la morphologie globale des micelles. Enfin, une dernière partie a été conceptualisée, dans laquelle l'auto-réparation se fait par « nano-gel » encapsulés et dispersés dans une membrane. Le « nano-gel » est à base d'un copolymère hydrophile en forme d'une étoile partiellement réticulée et qui doit être synthétisée par la technique de "Reversible Addition-Fragmentation Transfer" (RAFT) polymérisation. La synthèse d'un agent RAFT avec 4 bras pour la polymérisation a été accomplie, cependant, des travaux sont encore nécessaires pour valider la voie de synthèse vers la synthèse de « nano-gel » ainsi que son application pour le processus d'auto-réparation. / The objective of this thesis is to develop such kind of polymeric membranes which can repair themselves autonomously in an event of damage. Such damage in a membrane, if left undetected can pose serious health issues in some of the intended applications. In the first approach, a dynamic polymeric membrane based on ABA type triblock copolymer micelles has been prepared. The block “A” is represented by mechanically robust poly(styrene-co-acrylonitrile) copolymer while block “B” by relatively soft and flexible poly(ethylene oxide). When pressure is applied to the membrane, its morphology can be fine-tuned thanks to the compressible nature of micelles as well as intermicellar dynamic bridges. A range of porosities are accessible which can be regulated by pressure and thereby controlling the filtration performance. The same dynamic nature has also been utilized to display an effective pressure driven autonomous healing. The efficiency of healing process has been found to be dependent on the extent of damage, pressure value and time duration of application of pressure. Using the self-healing property of above membrane, “Direct Mode Translocation” of nanoparticles has also been studied. Four different classes of nanoparticles were used with varied intrinsic and extrinsic properties. The findings of the work prove that the size, shape and surface characteristics of the nanoparticles as well as the applied force govern the translocation process. In a second approach, a 2D and 3D reversible coating based on the self-assembly of micelles of diblock copolymer consisting of poly(methyl methacrylate) (PMMA) and poly(n-octadecyl methacrylate) (PODMA) blocks have been developed. The assembly of micelles is accomplished via so called “Zipper” effect, thanks to the long pendant chains of PODMA block. The same “zipper” effect plays the role of removing the coating easily by washing in a selective solvent, thus giving the ability to alter the surface of substrate for many times in reversible manner. The room temperature crystallization of PODMA block provides huge implications for a thermally assisted self-healing coating without affecting the global micelle morphology. Finally, another approach has been conceptualized in which self-healing occurs via encapsulated nano-gel dispersed within a membrane. The nano-gel is based on a partially crosslinked hydrophilic star shaped block copolymer which has to be synthesized by “Reversible Addition-Fragmentation Transfer” (RAFT) polymerization technique. The synthesis of a 4- arm RAFT agent for polymerization has been accomplished however ; a substantial amount of work is still needed to validate the synthetic route towards the nano-gel synthesis as well as its further application for the self-healing process.

Auto-réparation

Copolymère à blocs

Translocation

Membranes

Polymérisation radicalaire contrôlée

Self-healing

Block copolymer

Translocation

Membranes

Controlled radical polymerization

Développement de procédés de polymérisation catalysés par des complexes d'or / Development of polymerization processes catalyzed by gold complexes

Nzulu, Frida

30 October 2015

Ces travaux de thèse ont pour but de développer des procédés de polymérisation efficaces catalysés par des complexes organométalliques à base d'or. Dans une première partie, nous avons développé un nouveau procédé de polymérisation par polyaddition faisant intervenir des carbènes d'or formés par réaction de cycloisomérisation d'esters propargyliques catalysée par un complexe d'or carbophile. Des structures polymères originales et inédites composées d'un motif de répétition phényle vinylcyclopropane ont été proposées. Cette méthodologie a été appliquée à une variété d'esters propargyliques, tout en portant une attention particulière à l'augmentation de la solubilité et du degré de polymérisation des polymères. Une post-fonctionnalisation par l'hydrolyse de l'ester palmitate a été décrite et a permis d'accéder à une nouvelle architecture de polycétones. Des travaux préliminaires de conduction électrique ont montré que ces polycyclopropanes conjugués se comportaient comme des semi-conducteurs. Dans une seconde partie, une combinaison de deux processus de polymérisation associant, une polymérisation cationique vivante et une polymérisation radicalaire photo-induite pour la préparation de copolymères à blocs a été étudiée. Le complexe dinucléaire d'or(I) [Au2( μdppm)2]Cl2 a prouvé toute son efficacité pour catalyser la polymérisation par photo-ATRP d'acrylates en solution et en laminé, contrôlée par la lumière visible ou UVA. Finalement, des résultats préliminaires ont montré qu'il est possible de combiner une polymérisation cationique par RAFT catalysée par un acide de Lewis avec une polymérisation radicalaire photo-induite par RAFT sans utilisation de catalyseur photorédox. / The aim of this PhD work was to develop highly effective polymerization processes using gold complexes and the synthesis of original polymers. On the first research topic we have developed the first polymerization process through a gold carbenoic intermediate, leading to an original polymer composed by a phenyl vinylcyclopropyl monomer unit. This methodology was utilized to the polymerization of a variety of propargylic esters. Special attention has been paid to increase the solubility and the polymerization degree of the polymers. Post-functionnalization by hydrolysing the ester group leads to a new polyketone architecture. Preliminary electric studies showed that this conjugated polycyclopropane acts as a semi-conductor. The aim of the second research topic was to control efficiently the formation of block copolymers by combining living cationic and photo-induced radical polymerizations catalyzed in a one-pot procedure. A dinuclear gold(I) complex based photocatalyst [Au2(μ-dppm)2]Cl2 catalyzed efficiently polymerization of acrylates in solution and in laminate through an atom transfer radical polymerization process controlled by light exposure (visible or UV-A light). Finally, preliminary results showed it is possible to combine cationic reversible addition-fragmentation chain transfer polymerization catalyzed by a Lewis acid with radical reversible addition-fragmentation chain transfer polymerization without photoredox catalyst or radical initiator but only with an external stimuli, the light.

Cycloaddition

Polycyclopropanation

Complexes à base d'or

Photorédox

Polymérisation radicalaire

Polymérisation cationique

Radical polymerization

Cationic polymerization

Cycloaddition

Polycyclopropanation

540

Synthèse et caractérisation de polymères fonctionnalisés par des fonctions carbamoylméthylphosphonés - Etude de leurs propriétés de sorption/séparation / Synthesis and characterization of carbamoylmethylphosphonated functionalized polymers - Study of their sorption/separation properties

Gomes Rodrigues, Donatien

02 December 2015

Ces travaux de thèse portent sur la synthèse de nouveaux polymères hydrosolubles fonctionnalisés à des fins de complexation des lanthanides et/ou des actinides contenus dans des solutions de dissolution de minerai ou de recyclage.La synthèse d'un nouveau monomère fonctionnalisé par un motif carbamoylméthylphosphonate (cmp) nommé CPAAm6C a été réalisée. L'homopolymérisation par voie radicalaire conventionnelle de ce monomère a ensuite conduit à un matériau à la fois thermosensible et complexant. La présence d'une basse température critique de solution (ou LCST, généralement approximée avec la température de point de trouble) pourrait être valorisée dans le développement d'un procédé de séparation consistant dans un premier temps à complexer les cations en solution aqueuse (température inférieure à la LCST) puis à séparer les complexes polymères/cations formés à l'aide d'une étape de microfiltration (température supérieure à la LCST).Par hydrolyse de la fonction cmp, des polymères porteurs de fonctions acide carbamoylméthylphosphonique ont par ailleurs été préparés et caractérisés : le mhP(CPAAm6C) (monoacide) et hPCPAAm6C (diacide). L'étude de la sorption du gadolinium (lanthanide cible) sur les polymères fonctionnalisés P(CPAAm6C) et hP(CPAAm6C) en fonction de différentes conditions opératoires (concentration de gadolinium ou de polymère, pH, force ionique, température, composition des solutions) a permis de montrer que la sorption impliquait des mécanismes de coordination et/ou d'échange d'ions. Le caractère sélectif des polymères vis-à-vis du gadolinium, du thorium ou de l'uranium a également été mis en évidence. / The work reported in this manuscript deals with the synthesis of new functionalized water-soluble polymers with complexing properties towards lanthanides and/or actinides found in solutions of dissolution or recycling processes.The synthesis of a new functionalized monomer with a carbamoylmethylphosphonate (cmp) moiety, namely the CPAAm6C, was reported. Then, radical homopolymerisation of CPAAm6C was carried out, leading to material combining both thermosensitive and complexing properties. The presence of a lower critical solution temperature (LCST, generally approximated with the cloud point temperature) could be valorized in the development of a separation process in two steps consisting in first complexing the cations in aqueous solution (at a temperature below the cloud point) and then, in a second step, in separating the polymer/cations complexes using microfiltration (at a temperature above the cloud point).Hydrolysis of the cmp group was also considered and led to polymers bearing carbamoylmethylphosphonic acid groups: mhPCAAm6C(CPAAm6C) (monoacid) and hPCPAAm6C (diacid).The study of the sorption of gadolinium (targeted lanthanide) on P(CPAAm6C) and hP(CPAAm6C) functionalized polymers as a function of different operating conditions (concentration of lanthanide or polymer, pH, ionic strength, temperature, composition of the solution) allowed to provide information on the sorption mechanisms (coordination and ion exchange). Selectivity of the polymers toward gadolinium, thorium or uranium was also investigated.

Polymères fonctionnalisés

Polymérisation radicalaire

Sorption

Elements terres rares

Actinides

Complexation

Functionalized polymers

Radical polymerization

Sorption

Rare Earth Elements

Actinides

Complexation

Stimuli-responsive Novel Amphiphilic Polymers for Chemical and Biomedical Applications

Tam, K. C., Ravi, P., Dai, S., Tan, C. H.

01 1900

Amphiphilic polymers are a class of polymers that self-assemble into different types of microstructure, depending on the solvent environment and external stimuli. Self assembly structures can exist in many different forms, such as spherical micelles, rod-like micelles, bi-layers, vesicles, bi-continuous structure etc. Most biological systems are basically comprised of many of these organised structures arranged in an intelligent manner, which impart functions and life to the system. We have adopted the atom transfer radical polymerization (ATRP) technique to synthesize various types of block copolymer systems that self-assemble into different microstructure when subject to an external stimuli, such as pH or temperature. The systems that we have studied are: (1) pH responsive fullerene (C60) containing poly(methacrylic acid) (PMAA-b-C60); (2) pH and temperature responsive fullerene containing poly[2-(dimethylamino)ethyl methacrylate] (C₆₀-b-PDMAEMA); (3) other responsive water-soluble fullerene systems. By varying temperature, pH and salt concentration, different types microstructure can be produced. In the presence of inorganic salts, fractal patterns at nano- to microscopic dimension were observed for negatively charged PMAA-b-C60, while such structure was not observed for positively charged PDMAEMA-b-C60. We demonstrated that negatively charged fullerene containing polymeric systems can serve as excellent nano-templates for the controlled growth of inorganic crystals at the nano- to micrometer length scale and the possible mechanism was proposed. The physical properties and the characteristics of their self-assembly properties will be discussed, and their implications to chemical and biomedical applications will be highlighted. / Singapore-MIT Alliance (SMA)

Amphiphilic polymers

self-assembly

microstructures

atom transfer radical polymerization

ATRP

fullerene

poly(methacrilic acid)

Polyhydroxyl and Polyphosphorylcholine functionalized Silica for Hydrophilic interaction liquid Chromatography- Synthesis, characterization and application

Bui, Nhat Thi Hong

January 2012

This thesis focuses on the development of new stationary phases for use in hydrophilic interaction liquid chromatography using TRIS-based and phosphorylcholine typed monomers and porous silica particles as starting substrates. In this thesis, several ways of polymerizing highly hydrophilic mono­mers onto pore surfaces of silica supports are described, based on several “grafting from” schemes. “Controlled/living” radical polymerizations including atom transfer radical polymerization (ATRP) and iniferter-mediated polymerization in conjunction with conventional free radical polymerization are demonstrated to be successful tools for grafting different hydrophilic monomers (polyhydroxyl and phosphorylcholine [meth]acrylamide/acrylates) onto the silica surfaces. Reaction solvents are proven to play an essential role to achieve efficient graft polymerization of activated silica surfaces with these amphiphilic vinylic monomers, which is difficult because of their restricted access to the activated surface in solvents that can be used because of solubility constraints. Two tentacle TRIS-based polymer grafted silica, namely TRIS-WAX – TRIS functionality bonded to silica via a C–N–C imine bond and TRIS-Amide – TRIS bonded to silica via an amide bond, prove to be useful as stationary phases for hydrophilic interaction chromatography (HILIC).The TRIS-WAX exhibits a mixed mode hydrophilic partitioning and weak anion exchange (HILIC/WAX) retention mechanism while retention by hydrophilic partitioning is the dominant mechanism on the neutral TRIS-Amide phase which lacks weak anion exchange (WAX) properties. Interestingly, both these phases have selectivities that are radically different from most commercial HILIC stationary phases. Finally, a method is demonstrated for synthesizing a stratified (graft-copolymerized) silica material based on N,N′-methylenebisacrylamide and 2-methacryloyloxyethyl phosphorylcholine (MPC) using a “controlled/living” photoiniferter-mediated polymerization from the N,N-diethyldithiocarbamate iniferter moiety immobilized silica surfaces. This polymerization method proves to be successful for graft-blockcopolymerization of different highly hydrophilic monomers onto the activated surfaces of porous silica. In this way, silica surfaces are grafted with a cross-linked amide-based hydrogel, on top of which a tentacle zwitterionic phosphorylcholine-typed layer is synthesized. The resulted material proves to be useful for HILIC separations and possesses different selectivity for the tested organic acids compared to that of commercial ZIC-cHILIC stationary phase.

Hydrophilic Interaction Chromatography

HILIC

silica

TRIS

acrylamide/acrylate

ATRP

iniferter

N

N′-methylenebisacrylamide

MPC

stationary phase

Synthesis and modification of monodisperse polymer particles for chromatography

Limé, Fredrik

January 2008

Liquid chromatography is an analytical technique that is constantly facing new challenges in the separation of small molecules and large biomacromolecules. Recently the development of ultra high pressure liquid chromatography has increased the demand on sturdy particles as stationary phase. At the same time the particle size has decreased to sub-2 µm and packed into shorter analytical columns. This thesis deals with the development of new ways of preparing particulate polymer materials using divinylbenzene (DVB) as crosslinker. It includes a novel procedure for synthesizing monodisperse polymer particles by photoinitiated precipitation polymerization. A 150 W short arc xenon lamp was used to initiate the polymerizations. The synthesized particles are monodisperse and have an average particle size ranging from 1.5 to 4 μm depending on reaction conditions and have subsequently been used as grafting templates. The surface of DVB particles contains residual vinyl groups that serve as anchoring points for further functionalization via a variety of grafting schemes. Copolymerization with incorporation of 2,3-epoxypropyl methacrylate yielded pendant oxirane groups on the particle surface. Atom transfer radical polymerization (ATRP) was used to graft methacrylates from the surface resulting in a core-shell type material. A “grafting to” scheme was used to attach pre-made sulfopropyl methacrylate telomers onto particles containing oxirane rings. / Populärvetenskaplig sammanfattning på svenska: Vätskekromatografi är en analytisk kemisk teknik som ständigt står inför nya utmaningar när det gäller att separera allt från små organiska föreningar till stora makro¬molekyler. Denna avhandling beskriver tillverkning av polymera partiklar med exceptionellt jämn storleksfördelning och ytmodifiering av dessa, för användning som stationärfas i kromatografi¬kolonner. Polymeriserings¬tekniken som används är utfällnings¬polymerisering där lösningen UV-bestrålas av en 150 W xenonlampa. Monomeren (byggstenen) löses tillsammans med en intiator i ett lösningsmedel och efterhand som polymeriseringen fortskrider faller polymerpartiklarna ut. Polymerpartiklarna är gjorda av monomeren divinylbensen som fungerar som en tvärbindare, dvs att den länkar ihop flera kedjor till ett hårt litet nystan. Partiklarna växte till en storlek på 1,5 till 4 µm under två till fyra dygn. Efter tillverkningen är partiklarnas yta täckta av vinylgrupper som kan användas för att fästa funktionella polymerkedjor. Genom att tillföra monomeren 2,3-epoxipropyl¬metakrylat i polymeriseringen kunde man desutom få en partikelyta som innehöll epoxigrupper. Epoxigrupperna användes för att fästa positivt laddade polymerkedjor av bestämd längd. Materialet packades i en kromatografikolonn och användes för att separera en testlösning bestående av fyra proteiner. Partiklarna användes även som bas för ymppolymerisering där den vinyltäckta ytan fått reagera med vätebromid. Detta gör att partiklarna blir stora makroinitiatorer som kan användas för att på ett kontrollerat sätt låta polymerkedjor växa från ytan. I en undersökning ympades 2,3-epoxypropylmetakrylat från ytan på partiklarna och resultatet blev ett tjockt ytskikt. Epoxigrupperna kunde sedan hydrolyseras till dioler vilket gjorde partiklarna mer hydrofila.

Analytical chemistry

Analytisk kemi