Thermo-responsive microcarriers based on poly(N-isopropylacrylamide)

Zhang, J.N., Cui, Z.F., Field, R., Moloney, M.G., Rimmer, Stephen, Ye, H.

2015 April 1917

No / Microcarrier cell culture systems provide an attractive alternative to the conventional monolayer cell culture for cell amplification, due to their high surface area-to-volume ratio. Unlike enzymatic methods for removing cells from microcarriers after cell culture, which can lead to irreversible damage of the cells, microcarriers which release cells by temperature adjustment have been developed. This was achieved by grafting a temperature-responsive polymer, poly(N-isopropylacrylamide) (PNIPAAm), on the microcarrier surface. This review comprehensively presents various methods to prepare such thermo-responsive microcarriers based on PNIPAAm. These methods include the grafting-to technique, grafting-from technique, grafting-through technique, along with methods leading to PNIPAAm hydrogel beads, seeded polymerization, and non-covalent adsorption. The methods for controlling PNIPAAm grafting density, molecular weight and molecular architecture are also outlined. Further, the efficiency of cell attachment, proliferation and thermally-induced detachment of such thermo-responsive microcarriers is introduced and compared. (C) 2015 Elsevier Ltd. All rights reserved.

Thermo-responsive microcarrier

Poly(n-isopropylaciylamide)

Cell culture

Polymerisation

Transfer radical polymerization

Surface-initiated atrp

Membrane emulsification technique

Polystyrene latex-particles

Thermally reversible hydrogel

Core-shell microcapsules

Narrow size distribution

Modulated skin layers

Embryonic stem-cells

Cross-flow membrane

Emulsion polymerization in the presence of reactive PEG-based hydrophilic chains for the design of latex particles promoting interactions with cellulose derivatives / Polymérisation en émulsion en présence de chaînes polymères hydrophiles réactives à base de PEG pour la conception de particules de latex permettant des interactions avec des dérivés cellulosiques

Griveau, Lucie

07 December 2018

Dans cette thèse, des particules de polymère fonctionnalisées en surface avec des groupes poly (éthylène glycol) (PEG) ont été synthétisées pour favoriser leur interaction avec les dérivés cellulosique via liaisons hydrogène intermoléculaires. Deux voies de synthèse ont été proposées pour obtenir ses composites cellulose/latex.La première voie est basée sur l'auto-assemblage induit par polymérisation (PISA) pour former des nanoparticules fonctionnalisées avant leur adsorption sur un substrat cellulosique. La PISA tire profit de la formation de copolymères blocs amphiphiles dans l'eau en combinant la polymérisation en émulsion avec les techniques de polymérisation radicalaire contrôlées (RDRP). Ces dernières sont utilisées pour synthétiser des polymères hydrophiles agissant à la fois comme précurseur pour la polymerization en émulsion d'un monomère hydrophobe, et comme stabilisant des particules de latex obtenues. Deux techniques de RDRP ont été étudiées : les polymérisations RAFT et SET-LRP. Des polymères hydrophiles à base de PEG de faible masse molaire ont été synthétisés en utilisant ses deux techniques qui sont ensuite utilisés pour la polymérisation d'un bloc hydrophobe dans l'eau. Le transfert de l'agent de contrôle au site de la polymérisation était difficile en utilisant la SET-LRP en émulsion, conduisant à la formation de larges particules. En utilisant la RAFT en émulsion, des particules nanométriques ont été obtenues, avec un changement morphologique observé en fonction de la taille du segment hydrophobe, puis adsorbées sur des nanofibrilles de cellulose (CNF).La seconde voie utilise la polymérisation en émulsion classique réalisée en présence de nanocristaux de cellulose (CNC) conduisant à une stabilisation Pickering des particules de polymère. L'interaction cellulose/particule est assurée grâce à l'ajout d’un comonomère à type PEG. Une organisation a été visualisé dans laquelle plusieurs particules de polymère recouvrent chaque CNC / In this thesis, polymer particles surface-functionalized with poly(ethylene glycol) (PEG) groups were synthesized to promote their interaction with cellulose derivatives via intermolecular hydrogen bond. Two synthetic routes were proposed to obtain such cellulose/latex composites.The first route was based on the polymerization-induced self-assembly (PISA) to form functionalized polymer nanoparticles prior to adsorption onto cellulosic substrate. PISA takes advantage of the formation of amphiphilic block copolymers in water by combining emulsion polymerization with reversible-deactivation radical polymerization (RDRP) techniques. The latter were used to synthesize well-controlled hydrophilic polymer chains, acting as both precursor for the emulsion polymerization of a hydrophobic monomer, and stabilizer of the final latex particles. Two RDRP techniques were investigated: reversible addition-fragmentation chain transfer (RAFT), and single electron transfer-living radical polymerization (SET-LRP). Low molar mass PEG-based hydrophilic polymers have been synthesized using both techniques, used for the polymerization of a hydrophobic block in water. The transfer of controlling agent at the locus of the polymerization was challenging for SET-LRP in emulsion conditions leading to surfactant-free large particles. Nanometric latex particles were obtained via RAFT-mediated emulsion polymerization, with morphology change from sphere to fibers observed depending on the size of the hydrophobic segment, which were then able to be adsorbed onto cellulose nanofibrils (CNFs).The second route used conventional emulsion polymerization performed directly in presence of cellulose nanocrystals (CNCs) leading to Pickering-type stabilization of the polymer particles. Cellulose/particle interaction was provided thanks to the addition of PEG-based comonomer. Original organization emerged where CNCs were covered by several polymer particles

Poly(éthylène glycol) (PEG)

Polymerisation en émulsion

Nanofibrilles de cellulose (CNF)

Nanocristaux de cellulose (CNC)

Poly(ethylene glycol) (PEG)

Emulsion polymerization

Cellulose nanofibrils (CNFs)

Cellulose nanocrystals (CNCs)

540

Synthesis and photovoltaic applications of novel copolymers based on poly(3-hexylthiophene) / Synthèse et application en cellules solaires organiques de nouveaux copolymères à base de poly(3-hexylthiophène)

Erothu, Harikrishna

25 February 2011

Dans cette étude, des copolymères à blocs rigide-flexible comprenant des segments donneur [poly(3-hexylthiophène) régiorégulier, (rr-P3HT)] et accepteurs d’électrons (C60) ont été synthétisés. L’auto-assemblage en masse de ces copolymères à blocs avait pour objectif d’atteindre des morphologies dont la taille des domaines coïncide avec la distance idéale de transport de l’exciton (~10 nm) en vue d’utiliser ces systèmes comme matériaux de couche active dans les cellules photovoltaïques organiques de type P3HT-PCBM.La maîtrise et l'optimisation des conditions de synthèse de rr-P3HT de fonctionnalité terminale bien définie nous ont permis d'accéder à différentes architectures de copolymères linéaires di- et triblocs, constitués de P3HT comme bloc rigide et de polystyrène ou poly(4-vinylpyridine) comme bloc ‘flexible’. La fonctionnalisation du bloc flexible avec des dérivés du fullerène (C60 ou PCBM) a ensuite été réalisée et ces copolymères utilisés comme additifs pour stabiliser la morphologie de la couche active des cellules solaires organiques de type P3HT/PCBM. Les caractéristiques photovoltaïques des matériaux ainsi préparés ont été déterminées et corrélées aux analyses morphologiques de la couche active. / The performance of organic photovoltaic cells mainly depends on the active layer nano-morphology. Rod-coil block copolymers (BCPs) are well known in their ability to self-assemble into well-ordered nanoscopic morphologies. BCPs containing electron-donor and acceptor segments are of particular interest for use in photovoltaic cells because electronic light-excited states exist over distances similar to the typical size of block copolymer domains (~10 nm). Therefore, we designed novel donor-acceptor BCPs to exploit this coincidence in dimensions. This thesis is focused on BCPs based on regioregular poly(3-hexylthiophene) (rr-P3HT) due to its high hole mobility and good processibility from various solvents. Simplified and versatile syntheses of donor-acceptor rod-coil di- and tri- BCPs consisting of the donor block P3HT (rod) and polystyrene or poly(4-vinylpyridine) (coil) blocks to carry the acceptor C60 in different ways were developed. These materials were used as surfactants to stabilize the nano-morphology of reference P3HT: [6,6]-phenyl-C61-butyric acid methyl ester (PCBM) based devices. Photovoltaic characterizations were then tied to copolymer structural data with the help of AFM and a range of complementary characterization techniques.

Cellules photovoltaïques organiques

Copolymères à blocs rigide-flexible

Polymérisation GRIM

Poly(3-hexylthiophène) fonctionnel

Morphologie

Compatibilisation

Organic photovoltaic cells

Rod-coil block copolymers

GRIM polymerization

Functional poly(3-hexylthiophene)

Controlled radical polymerization

Anionic polymerization

C60 grafting

Nano-structuration

Limites et potentiels de la polymérisation radicalaire par ouverture de cycle pour la synthèse de polyesters / Limits and Potential of the Radical Ring-Opening Polymerization for the Synthesis of Polyesters

Tardy, Antoine

18 April 2014

La Polymérisation Radicalaire par Ouverture de Cycle (R-ROP) est une méthode de synthèse de polymères contenant des fonctions chimiques de choix dans le squelette carboné grâce à un mécanisme d'addition-fragmentation. L'utilisation de monomères spécifiques, les Acétals Cétènes Cycliques (CKA), permet dans certaines conditions l'obtention de polyesters aliphatiques dont la propriété de (bio)dégradation présente de nombreuses applications. Cette méthode relativement peu étudiée depuis les années 1980 présente un fort potentiel mais également de nombreuses limites. Ce travail de thèse a consisté à comprendre l'origine de ces limites pour tenter d'y apporter des solutions, grâce à une approche combinée expérience-théorie.Nous avons montré que l'obtention exclusive de polyesters découle d'une compétition cinétique et que le comportement des différents monomères s'explique par des interactions orbitalaires dépendant de la géométrie, la flexibilité et la substitution des cycles. D'autre part, nous avons mis en évidence l'extrême difficulté de propagation des monomères propageant via des radicaux stabilisés par des cycles aromatiques. Cette faible réactivité inhérente à la double liaison riche en électrons des CKA est également la cause de l'incorporation restreinte des monomères cycliques en copolymérisation avec des monomères vinyliques usuels. La rationalisation de la copolymérisation a été mise à profit pour réaliser des copolymérisations de type statistique et alternée. Enfin, l'étude du contrôle de la R-ROP par les nitroxydes a montré la présence de réactions secondaires propres à ce système et permettant actuellement un contrôle partiel de la polymérisation. / The Radical Ring-Opening Polymerization (R-ROP) is a synthetic pathway to introduce chemical functions into a polymer backbone due to an addition-fragmentation mechanism. Using specific monomers like Cyclic Ketene Acetals (CKA) in the right conditions allows preparing aliphatic polyesters which have numerous applications thanks to their (bio)degradability. This method has been quite faintly investigated since the 1980s and even if it has a great potential, it suffers of numerous limitations. This PhD work consisted in the understanding of those limitations to try bringing solutions to them, with a combined approach of experiments and theory.We first demonstrated that the exclusive preparation of polyesters comes from a kinetic competition. The behavior of the distinct monomers is explained by orbital interactions depending on the geometry, flexibility and substitution of the cycles. Then, we highlighted the extremely difficult propagation of the monomers propagating with stabilized aromatic radicals. This low reactivity inherent to the electron-rich double link of the CKAs is also the cause of low polyester introduction during the copolymerization with usual vinyl monomers. We took advantage of the CKA copolymerization rationalization to realize statistical and alternate copolymerizations. At last, the study of the nitroxide mediated R-ROP demonstrated the occurrence of side reactions characteristic of this system that allow at present a partial control of the polymerization.

Acétal cétène cyclique

Mdp

Bmdo

Polyesters aliphatiques

Modélisation moléculaire

Dft

Simulations PREDICI

Polymérisation radicalaire contrôlée

Nitroxyde

Radical Ring-Opening Polymerization

Cyclic Ketene Acetal

Mdp

Bmdo

A.liphatic polyesters

Molecular modeling

Dft

PREDICI modeling studies

Controlled radical polymerization

Nitroxide

Strukturiranje polimernih mreža na osnovu akrilamida i akrilne kiseline / Structuring of polymer networks based on acrylamide and acrylic acid

Erceg Tamara

28 September 2019

<p style="text-align: justify;">U ovom radu sintetisani su hidrogelovi na osnovu akrilamida i akrilne kiseline, radikalnom polimerizacijom, primenom konvencionalne i mikrotalasne metode sinteze. Varirani su početni odnosi monomera i udeo umreživača, u cilju ispitivanja uticaja sastava reakcione sme&scaron;e na svojstva dobijenih hidrogelova. Optimizovani su uslovi sinteze u mikrotalasnom polju kao brže, jednostavnije i ekonomičnije metode. U cilju uspostavljanja korelacije između mehanizma sinteze, strukture i svojstava dobijenih hidrogelova, primenom relevantnih metoda karakterizacije, upoređena su apsorpciona, reolo&scaron;ka, toplotna i strukturna svojstva hidrogelova dobijenih dvema metodama.&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; Ustanovljeno je da se mikrotalasnom metodom sinteze na brži i jednostavniji način uz smanjen utro&scaron;ak vremena i energije dobijaju hidrogelovi konkurentni onima koji se dobijaju konvencionalnim zagrevanjem u vodenom rastvoru. Drugi deo doktorata obuhvata sintezu hidrofilnih polimernih mreža na osnovu natrijum karboksimetilceluloze (NaCMC) i karboksilnih kiselina, od kojih je jedna serija sintetisana prožimanjem linearnim kopolimerima akrilamida i akrilne kiseline u cilju povećanja potencijala primene u floku-lacione svrhe. Rezultati ispitivanja svojstava bubrenja, strukturnih toplotnih i flokulacionih svojstava pokazali su međusobno slaganje. Dobijeni rezultati pokazali su da od primenjenih karboksilnih kiselina, linunska kiselina u udelu od 15% u odnosu na masu NaCMC daje hidrogelove najboljih svojstava. Kombinacijom ove mreže sa kopolimerom akrilamida i akrilne kiseline u masenom odnosu 10/90, stvara se teorijska platforma za dobijanja flokulanta koji bi mogao da pokaže visoku efikasnost u preči&scaron;ćavanju vode u kojoj dominiraju pozitivno naelektrisane čestice, pravilnim izborom parametara flokulacije.</p> / <p>In this paper, hydrogels based on acrylamide and acrylic acid were synthesized using conventional and microwave synthetic methods via free-radical polymerization. The initial monomers ratio and amount of crosslinking agent were varied in order to investigate the effect of the composition of the reaction mixture on the properties of the obtained hydrogels. The conditions of synthesis in the microwave field as faster simpler and more economical method have been optimized. In order to establish a correlation between the mechanism of synthesis, structure and properties of the obtained hydrogels using the relevant methods of characterization, the absorption, rheological, thermal and structural properties of the hydrogels obtained by the two methods were compared. It has been found that the microwave synthesis is a faster and simpler method, which enables reduced consumption of time and energy and produces hydrogels competitive to those ones obtained by conventional heating in aqueous solution. The second part of the thesis includes the synthesis of hydrophilic polymer networks based on sodium carboxymethylcellulose (NaCMC) and carboxylic acids, whereby one series is synthesized by interpenetration of the network using the linear acrylamide and acrylic acid copolymers in order to increase the potential application of hydrogels for flocculation purposes. The results of measurements of swelling, structural, thermal and flocculation properites have shown mutual agreement. The obtained results have shown that among applied carboxylic acids, citric acid in the amount of 15% per mass of NaCMC, has given the hydrogels with the best properties. The Combination of this network with a copolymer of acrylamide and acrylic acid in a mass ratio of 10/90 has created a theoretical platform for the production of flocculant which could show high efficacy in purifying of water dominated by positively charged particles.</p>

Σύνθεση και χαρακτηρισμός υβριδικών ανόργανων/οργανικών νανοδομημένων στερεών καταλυτών

Καραμήτρου, Μέλπω

11 July 2013

Η δυνατότητα να συνδυαστούν οι ιδιότητες οργανικών και ανόργανων συστατικών σε ένα μοναδικό νανοδομημένο υβριδικό υλικό αποτελεί μία σημαντική επιστημονική πρόκληση στο σχεδιασμό υλικών, τα οποία μπορούν να εμφανίζουν νέες βελτιωμένες ιδιότητες και να τύχουν προηγμένων εφαρμογών. Τα υβριδικά υλικά, γενικά, μπορούν να ταξινομηθούν σε δύο μεγάλες κατηγορίες: στην κατηγορία I (class I), όπου οι δύο φάσεις συνδυάζονται μέσω ασθενών αλληλεπιδράσεων, και στην κατηγορία II (class II), όπου οι δύο φάσεις είναι σταθερά συνδεδεμένες. Στην παρούσα εργασία διερευνήθηκε η δυνατότητα εφαρμογής νανοδομημένων υβριδικών υλικών ως ετερογενείς καταλύτες στη διεργασία παραγωγής βιοντίζελ από διαφόρων ειδών έλαια. Κατά τη διεργασία αυτή, η οποία καλείται μετεστεροποίηση ή μεθανόλυση, τριγλυκερίδια αντιδρούν με μια αλκοόλη παρουσία ισχυρού οξέος ή βάσης προς παραγωγή εστέρων και γλυκερίνης. Σε πρώτη φάση, εστιάσαμε στη σύνθεση και το χαρακτηρισμό class I και class II υβριδικών οργανικών/ανόργανων υλικών αποτελούμενων από έναν ανόργανο πυρήνα διοξειδίου του πυριτίου (silica), ο οποίος θα περιβάλλεται από πολυμερικές αλυσίδες. Έτσι, στην προσπάθεια σύνθεσης υβριδικών υλικών class I αξιοποιήθηκαν οι πιθανές αλληλεπιδράσεις καθαρών και αμινοτροποποιημένων νανοσωματιδίων διοξειδίου του πυριτίου με υδατοδιαλυτά συμπολυμερή P(SSΗ-co-MA) του στυρενοσουλφονικού οξέος (SSH), με το μηλεϊνικό οξύ (ΜΑ), τα οποία φέρουν τόσο καρβοξυλικές όσο και σουλφονικές ομάδες. Ως αποτέλεσμα του όξινου χαρακτήρα των πολυμερών, τα υβριδικά νανοσωματίδια θα μπορούσαν δυνητικά να χρησιμοποιηθούν ως όξινοι καταλύτες κατά την παραγωγή του βιοντίζελ. Στην προσπάθεια σύνθεσης class II υβριδικών υλικών αξιοποιήθηκε κυρίως ο πολυμερισμός ελευθέρων ριζών μέσω μεταφοράς ατόμου (ATRP), μονομερών όπως στυρενοσουλφονικό νάτριο (SSNa), Ν-ισοπροπυλακρυλαμίδιο (NIPAM) και 2-(διμεθυλαμινο)μεθακρυλικός αιθυλεστέρας (DMAEMA). Για την εκκίνηση του πολυμερισμού χρησιμοποιήθηκαν νανοσωματίδια silica χημικά τροποποιημένα με 3-αμινοπροπυλοτριαιθοξυσιλάνιο και ακολούθως με 2-χλωροπροπιονυλοχλωρίδιο. Εναλλακτικά, χρησιμοποιήθηκαν νανοσωματίδια silica χημικά τροποποιημένα με 3-χλωροπροπυλoτριαιθοξυσιλάνιο (ATRP πολυμερισμός), ή βινυλοτριμεθοξυσιλανιο (πολυμερισμός ελευθέρων ριζών, FRP). Ο χαρακτηρισμός των δειγμάτων κατά περίπτωση έγινε με φασματοσκοπία πυρηνικού μαγνητικού συντονισμού υδρογόνου (1H NMR), φασματοσκοπία υπερύθρου με μετασχηματισμό Fourier (FTIR), θερμοσταθμική ανάλυση (TGA) και τιτλοδότηση οξέος-βάσεως. Στο τελευταίο μέρος της εργασίας ελέγχθηκε η καταλυτική δράση κάποιων εκ των συντεθέντων υλικών στην αντίδραση μεθανόλυσης της τριοξικής γλυκερόλης, χρησιμοποιώντας την τεχνική 1H NMR. Διαπιστώθηκε πως τα αμινοτροποποιημένα νανοσωματιδία silica εμφανίζουν σημαντική καταλυτική δράση. Αντίθετα η ικανότητα των υβριδικών οργανικών/ανόργανων υλικών silica-NH2(B)/P(SSH50-co-MA50), silica-NH2(D)/P(SSH75-co-MA25), και silica-VTMS-PDMAEMA να δρουν ως όξινοι ή βασικοί καταλύτες της ίδιας αντίδρασης είναι πολύ περιορισμένη. / The possibility to combine the properties of organic and inorganic components in a unique nanostructured hybrid material is a major scientific challenge in designing novel materials exhibiting improved properties and finding advanced applications. Hybrid materials generally can be classified into two categories: class I, where the two phases are combined through weak interactions, and class II, where the two phases are covalently connected. The aim of the present study was to develop novel hybrid organic/inorganic nanomaterials, potentially applied as heterogeneous catalysts in the biodiesel production process. In this process, called transesterification or methanolysis, triglycerides from various oils react with an alcohol in the presence of a strong acid or base to produce the respective esters and glycerin. In the first part of this work, we focused on the synthesis and characterization of class I and class II hybrid organic/inorganic nanomaterials consisting of an inorganic silicon dioxide (silica) core and a polymer shell. Thus, for the class I hybrid materials we took advantage of the weak interactions between net or amino-functionalized silica nanoparticles and water-soluble P(SSH-co-MA) copolymers of styrene sulfonic acid (SSH), with maleic acid (MA), carrying both carboxyl and sulfonic groups. These hybrid nanoparticles could potentially be used as acidic catalysts in the production of biodiesel, as a consequence of the acidic nature of the polymer used. For the class II hybrid materials, we mostly applied atom transfer radical polymerization (ATRP) of monomers such as sodium styrene sulfonate (SSNa), N-isopropylacrylamide (NIPAM) and 2-(dimethylamino) ethyl methacrylate (DMAEMA). To initiate the polymerization, silica nanoparticles chemically modified with 3-aminopropyltriethoxysilane and subsequently with 2-chloropropionylchloride were used. Alternatively, we also used silica nanoparticles chemically modified with 3-chloropropyltriethoxysilane (ATRP polymerization), or vinyltrimethoxysilane (free radical polymerization, FRP). In all cases, the products were characterized through a combination of techniques, such as proton nuclear magnetic resonance spectroscopy (1H NMR), Fourier transform infrared spectroscopy (FTIR), thermogravimetric analysis (TGA) and acid-base titration. In the latter part of this work, the catalytic activity of some materials in the methanolysis process of glycerol triacetate was investigated, using the 1H NMR technique. It was found that the aminofunctionalized silica nanoparticles exhibit significant catalytic activity, whereas the ability of the hybrid materials silica-NH2(B)/P(SSH50-co-MA50), silica-NH2(D)/P(SSH75-co-MA25) and silica-VTMS-PDMAEMA to act as acidic or basic catalysts is very limited.

Βιοντίζελ

Μετεστεροποίηση

Μεθανόλυση

620.118

Silica nanoparticles

Aminofunctionalized nanoparticles

Polymer/silica nanoparticles

Biodiesel

Transesterification

Methanolysis

Heterogeneous catalysts

Synthesis of polyelectrolyte brushes on silica-based substrates through surface-initiated polymerization : brush characterization and responsiveness to variation in pH and ionic strength

Borozenko, Olga

12 1900

No description available.

Brosse de polymère

Conformation brosse

Poly(acide acrylique)

pH- et force ionique

Stimuli-répondant

Ellipsometrie

Dégreffage de brosses et stabilité

Propriétés de surface

Amorceur siloxane

Polymer brush

Poly(acrylic acid)

Brush conformation

pH- and ionic strength responsiveness

Ellipsometry

Brush degrafting and stability

Surface properties

Siloxane initiator

Synthesis and Characterization of Polymeric Magnetic Nanocomposites for Damage-Free Structural Health Monitoring of High Performance Composites

Hetti, Mimi

13 October 2016

The poly(glycidyl methacrylate)-modified magnetite nanoparticles, Fe3O4-PGMA NPs, were investigated and applied in nondestructive flaw detection of polymeric materials in this research. The Fe3O4 endowed magnetic property to the materials for flaw detection while the PGMA promoted colloidal stability and prevented particle aggregation. The magnetite nanoparticles (Fe3O4 NPs) were successfully synthesized by coprecipitation and then surface-modified with PGMA to form PGMA-modified Fe3O4 NPs by both grafting-from and grafting-to approaches. For the grafting-from approach, the Fe3O4 NPs were surface-functionalized with α-bromo isobutyryl bromide (BIBB) to form BIB-modified Fe3O4 NPs (Fe3O4-BIB NPs) with covalent linkage. The resultant Fe3O4-BIB NPs were used as surface-initiators to grow PGMA by surface-initiated atom transfer radical polymerization (SI-ATRP). For the grafting-to approach, the Fe3O4 NP were surface-functionalized with (3-mercaptopropyl)triethoxysilane (MCTES) to form MCTES-modified Fe3O4 NPs (Fe3O4-MCTES NPs). The PGMA with Br-end group was pre-synthesized by ATRP and then was grafted to the surface of the Fe3O4-MCTES NPs by coupling reaction. Both bare and modified Fe3O4 NPs exhibited superparamagnetism and the existence of iron oxide in the form of Fe3O4 was confirmed. The particle size of individual Fe3O4 NPs was about 8 – 24 nm but they aggregated to form clusters. The PGMA-modified NPs formed stable dispersion in chloroform and had larger cluster sizes than the unmodified ones because of the PGMA polymer layer. However, the uniformity of the NP clusters could be improved with PGMA surface grafting. The PGMA surface layer of the grafting-from (Fe3O4-gf-PGMA) NPs was thin and dense while that of the grafting-to (Fe3O4-gt-PGMA) NPs was thick and loose. The hydrodynamic diameters (Zave) of Fe3O4-gf-PGMA NP clusters could be controlled between 176 to 643 nm, dependent on the PGMA contents and reaction conditions. During SI-ATRP, side reactions happened and caused NP aggregation as well as increase of size of NP clusters. However, the aggregation has been minimized through optimization of reaction conditions. Oppositely, Zave values of Fe3O4-gt-PGMA NPs had little variation of about 120 – 190 nm. And the PGMA content of the Fe3O4-gt-PGMA NPs was limited to 12.5% because of the spatial hindrance during grafting process. The saturation magnetization (Ms) of the unmodified Fe3O4 NPs was about 77 emu/g, while those of the grafting-from and grafting-to Fe3O4-PGMA NPs were 50 – 66 emu/g and 63 – 70 emu/g, respectively. For Fe3O4-PGMA NPs with similar Fe3O4 contents, the grafting-to NPs had slightly higher Ms than the grafting-from counterparts. In addition, the Ms of both kinds of the Fe3O4-PGMA NPs with higher Fe3O4 content (> 87%) were also higher than that of the fluidMAG-Amine, the commercially available amine-modified MNPs. Besides, both kinds of Fe3O4-PGMA NPs also had much higher Fe3O4 contents and Ms values than most of the reported PGMA-modified MNPs. The magnetic epoxy nanocomposites (MENCs) were prepared by blending the modified Fe3O4 NPs into bisphenol A diglycidyl ether (BADGE)-based epoxy system and the distributions of both kinds of the PGMA-modified NPs were much better than that of the oleic acid-modified Fe3O4 NPs. Similar to the NPs, the MENCs also exhibited superparamagnetism. By cross-section TEM observation, the grafting-to Fe3O4-PGMA NPs formed more homogeneous distributions with smaller cluster size than the grafting-from counterparts and gave higher Ms of the MENCs. Nondestructive flaw detection of surface and sub-surface defects could be successfully achieved by brightness contrast of images given through eddy current testing (ET) method, which is firstly reported. The mechanical properties of the materials were influenced very slightly when 2.5% or lower Fe3O4-gt-PGMA NPs were present while the presence of the Fe3O4-gf-PGMA NPs (1 – 2.5 %) gave mild improvement of the storage modulus and increase of the glass-rubber transition temperature(Tg) of the MENCs. Furthermore, the Fe3O4-PGMA NPs could be evenly coated onto the functionalized ultra-high molecular weight poly(ethylene) (UHMWPE) textiles. The Fe3O4-gt-PGMA NPs were coated on the textile in order to prepare NP-coated textile-reinforced composite. Preliminary result of ET measurement showed that the Fe3O4-gt-PGMA NPs coated on the textiles could visualize the structure of the textile hidden inside and their relative depth. Accordingly, the incorporation of MNPs to polymers opens a new pathway of damage-free structural health monitoring of polymeric materials.

Magnetit-Nanopartikel

Atomübertragungsradikalpolymerisation

Oberfläche initiierten ATRP

magnetische Nanokomposite

beschädigungsfreie Strukturüberwachung

Wirbelstromprüfung

zerstörungsfreie Fehlererkennung

Poly (Glycidylmethacrylat)

faserverstärkten Epoxid-Komposite

Magnetite nanoparticles

Atom transfer radical polymerization

Surface-initiated ATRP

Magnetic nanocomposites

Damage-free structural health monitoring

Eddy current testing

Nondestructive flaw detection

poly(glycidyl methacrylate)

fiber-reinforced epoxy composites

ddc:540

rvk:VE 9857

Synthèse de latex de poly(fluorure de vinylidène) (PVDF) sans tensioactif à l’aide de la polymérisation radicalaire contrôlée de type RAFT / Synthesis of surfactant-free poly(vinylidene fluoride) (PVDF) latexes via RAFT emulsion polymerization

Fuentes-Exposito, Mathieu

26 September 2019

Les travaux réalisés portent sur la synthèse de nanoparticules de PVDF à l’aide de la polymérisation radicalaire contrôlée (PRC) par transfert de chaîne réversible par addition-fragmentation (RAFT) en émulsion. Dans un premier temps, un méthoxy poly(éthylène glycol) commercial porteur d’une fonction hydroxyle (PEG-OH) a été employé pour la stabilisation des particules de PVDF. Cette stabilisation est assurée par des réactions de transfert irréversible opérant le long des chaînes de PEG conduisant à la formation in situ d’un stabilisant de type copolymère greffé. Par la suite, un PEG modifié chimiquement à partir du PEG-OH, portant à son extrémité de chaîne une fonction xanthate (macroRAFT, PEG-X), réactive et réactivable, a été utilisé. Les expériences réalisées en présence de ce macroRAFT ont démontré une forte implication de l’extrémité xanthate dans le procédé de polymérisation en émulsion du VDF. En effet, des particules stables de l’ordre de 70 nm de diamètre sont obtenues, alors que l’utilisation de PEG-OH conduit à des tailles beaucoup plus importantes (200 nm). Cette tendance est confirmée lors de l’étude de l’impact de divers paramètres comme la masse molaire de la chaîne PEG ou encore la quantité d’amorceur. Des analyses complémentaires (tension de surface et calorimétrie différentielle à balayage) ont permis de comparer le taux d’ancrage de PEG-X et de PEG-OH. Les quantités en macroRAFT ont ensuite été augmentées dans le but d’obtenir des particules composées de copolymères à blocs. Des analyses RMN approfondies ont été menées pour identifier les espèces créées lors de la polymérisation en émulsion du VDF lorsque PEG-OH et PEG-X sont utilisés en tant que stabilisant. Par comparaison, des PEG portant des fonctions réactives de types (méth)acrylate et thiol ont également été employés comme stabilisant et leurs efficacités comparées à celles de PEG-OH et de PEG-X. Par ailleurs, d’autres architectures à base de PEG ont été évaluées en utilisant un macroRAFT difonctionnel (X-PEG-X) et un polymère greffé (PPEGA-X). Enfin, des latex de PVDF ont été synthétisés en présence de macroRAFT de type poly(acide (méth)acrylique) obtenus par polymérisation RAFT de l’acide acrylique ou méthacrylique en présence d’un trithiocarbonate ou d’un xanthate. Comme précédemment, plusieurs paramètres ont été variés comme la masse molaire des chaînes macromoléculaires, la quantité d’amorceur et la quantité de macroRAFT. Ces études ont encore une fois démontré la forte implication des extrémités RAFT dans la stabilisation des particules de PVDF / This work describes the synthesis of self-stabilized PVDF particles by combining the advantages of emulsion polymerization with those of controlled radical polymerization (CRP) using the RAFT process. First, a commercial methoxy poly(ethylene glycol) carrying a hydroxyl function (PEG-OH) was used for the stabilization of PVDF particles. The stabilization is provided by irreversible transfer reactions occurring along the PEG-OH chains leading to the formation of a grafted copolymer stabilizer in situ. This PEG-OH was then chain-end functionalized to introduce a xanthate group (macroRAFT, PEG-X). The experiments carried out in the presence of this macroRAFT demonstrated a strong implication of the xanthate chain-end in the VDF emulsion polymerization process. Indeed, particle sizes of 200 nm and 70 nm were obtained in the presence of PEG-OH and PEG-X, respectively. This trend was confirmed during the study of the impact of various parameters such as the molar mass of the PEG chain or the initiator amount. Additional analyses (surface tension measurement and differential scanning calorimetry) allowed to compare the anchoring efficiency of PEG-X and PEG-OH. The macroRAFT amount was then increased to form particles composed of block copolymer. In-depth NMR analyses were then conducted to identify the species created during the VDF emulsion polymerization process in the presence of PEG-OH and PEG-X. In comparison, PEGs carrying reactive functions such as (meth)acrylate and thiol were used as stabilizers and their efficiencies compared to those of PEG-OH and PEG-X. The macroRAFT architecture was also varied using a difunctional macroRAFT (X-PEG-X) and a grafted polymer (PPEGA-X). Finally, PVDF latexes were synthesized with poly((meth)acrylic acid) (P(M)AA) functionalized by either a trithiocarbonate or a xanthate. Like previously, several parameters were varied such as the macromolecular chain length, the initiator amount and the macroRAFT amount. Again, these studies demonstrated the strong impact of the RAFT chain-end in the stabilization of PVDF particles

Fluorure de vinylidène (VDF)

Poly(éthylène glycol) (PEG)

Poly(acide (méth)acrylique) (P(M)AA)

Polymérisation en émulsion

Vinylidene fluoride (VDF)

Poly(ethylene glycol) (PEG)

Poly((meth)acrylic acid) (P(M)AA)

Controlled radical polymerization (CRP)

Emulsion polymerization

540

Conception de surfaces bio-inspirées à mouillabilité contrôlée à partir de polymères conducteurs / Conception of bioinspired surfaces with controlled wettability from conducting polymers

Mortier, Claudio

18 December 2017

Le contrôle de la mouillabilité de surface est un enjeu majeur pour le développement de matériaux innovants liés aux nano, bio et smart technologies. La mouillabilité est fonction de deux paramètres majeurs : l’énergie de surface du matériau et sa morphologie. La combinaison de ces deux paramètres est à la base de phénomènes tels que la super/parahydrophobie ou la superoléophobie. Ces capacités extrêmes à repousser les liquides avec soit une forte ou faible adhésion sont des propriétés de surface très intéressantes pour de multiples applications industrielles. La présente thèse propose l’étude d’une série de dérivés du polypyrrole élaborés par électrodéposition permettant d’influencer les paramètres régissant la mouillabilité de surface. Par cette approche, il a été possible d’élaborer des surfaces aux morphologies diverses avec une gamme de mouillabilité complète. Les différentes fonctionnalisations par des groupements hydrophobes greffés sur différentes positions préférentielles du monomère ont conduit à l’élaboration de surfaces para et superhydrophobes mettant en évidence l’impact de l’énergie de surface et de la morphologie sur la mouillabilité. Des études préliminaires ont mis en évidence la possibilité d’obtenir des morphologies variées allant de sphères jusqu’à des fibres à l’échelle du micro/nanomètre. Finalement, ces travaux contribuent à un contrôle en amont de la mouillabilité et de la morphologie de surface pour de nombreuses applications potentielles comme les matériaux collecteurs d’eau, les membranes séparatrices de liquide ou bien les revêtements auto nettoyant. / The control of the surface wettability is a key point for the development of innovative materials in several domains such as nano-, bio- and smart-technologies. The wettability is a function of two main parameters of the materials, such as the surface energy and the surface morphology. The combination of these two parameters allows to observe wetting phenomena as super/parahydrophobicity and superoleophobicity. These extreme abilities to repel liquids with different adhesion behaviors are very interesting properties for several industrial applications. This work presents a series of polypyrrole derivatives elaborated by electrodeposition allowing to influence the parameters driving the surface wettability. Following this approach, it was possible to develop surfaces with several types of morphology and different wetting behaviors from a low to high wettability. The different functionalizations using hydrophobic compounds grafted on various preferential positions on the monomer core yielded to para and superhydrophobic surfaces showing the impact of the surface energy and morphology on the wettability. Thanks to preliminary studies, it was showed the possibility to obtain several morphologies from spherical aggregates to fibers at the micro/nano scale. Finally, this work contributes to an upstream control of the surface wettability and morphologies for many potential applications such as water harvesting, separation membranes and self-cleaning coatings.

Surfaces superhydrophobes

Propriété autonettoyante

Micro/nano morphologie

Mouillabilité

Électrodéposition

Polymérisation radicalaire

Caractérisation de surface

Effet lotus

Effet pétale

Nanotehcnologies

Smart-materials

Superhydrophobic surfaces

Self-cleaning property

Micro/nano morphology

Wettability

Electrodeposition

Radical polymerization

Surface characterization

Lotus effect

Petals effect

Nanotechnologies

Smart-materials