Synthesis and Characterization of Arborescent (Dendritic) Polystyrenes Prepared by Raft Polymerization

Heidenreich, Andrew J.

10 August 2011

No description available.

Polymer Chemistry

branched polymers

arborescent

hyperbranched

size exclusion chromatography

polystyrene

Synthesis and Characterization of Ionically Bonded Diblock Copolymers

Feng, Lei

January 2013

No description available.

Polymers

block copolymer

supramolecular polymer

RAFT polymerization

ionic bond

Design and Synthesis of Supramolecular Structures for the Controlled Release of Sulfur Signaling Species

Carrazzone, Ryan Joseph

08 February 2022

In the early 2000s, hydrogen sulfide (H₂S) was added to the family of molecules known as gasotransmitters, a class of endogenously produced and freely diffusing biological signaling molecules. Since this discovery, biologists and chemists have sought to understand the physiological roles of H₂S and to elucidate the potential benefits of exogenous H₂S delivery. As a result, many synthetic small molecule donor compounds have been created to deliver H₂S in response to various biologically relevant stimuli. Furthermore, macromolecular and supramolecular H₂S donor systems have been created to protect donors in the biological milieu, extend release kinetics, or control H₂S release conditions. Thus, H₂S-donating nanostructures with precisely tuned release rates provide invaluable tools for further investigating the biological roles and therapeutic potential of H₂S. This work describes two polymer micelle systems for the controlled delivery of H₂S. The first system is based on H2S-releasing polymer amphiphiles with varying degrees of a plasticizing comonomer incorporated into the core-forming block. The glass transition temperature of the core-forming block varied predictably with incorporation of the plasticizing comonomer. Accordingly, the half-life of H₂S release decreased from 4.2 h to 0.18 h with increasing core-forming block mobility. The second system is based on H₂S releasing polymer amphiphiles with varying degrees of crosslinking in the core-forming block. The crosslinked system was designed to achieve control over H₂S release rate with minimal dilution of donor in the core-forming block. The half-life of H₂S release increased from 117 min to 210 min with increasing crosslink density in the core-forming block, further demonstrating that H₂S release rates can be precisely controlled by tuning micelle core mobility. Beyond control over H₂S release rate, further study of the biological roles of H₂S requires donor systems with precisely triggered release. To this end, this dissertation also discusses efforts to investigate fundamental micelle–unimer relationships. This section includes an evaluation of the impact of core-forming block mobility on micelle–unimer coexistence utilizing a model polymer amphiphile system. Unimer populations correlated with glass transition temperatures of the core-forming block, suggesting the need to consider micelle core mobility when discussing polymer chain phase behavior of amphiphilic block copolymers. Finally, this work discloses new methods for the radical polymerization of poly(olefin sulfones) with control over molecular weight. POSs are a unique class of polymers with great potential for stimuli-responsive depolymerization to generate sulfur dioxide (SO₂), a signaling gas related to H₂S. / Doctor of Philosophy / Hydrogen sulfide (H2S) is commonly known for its pungent odor and toxicity. Despite this negative stigma, H2S has been revealed as a vital signaling molecule in both plants and animals. This discovery has prompted the coordination of biologists and chemists in an effort to better understand the roles of H2S in the body. Driven by this motive, great interest has centered around the development of finely tuned molecules designed to generate H2S in the body, termed H2S donors. A variety of synthetic H2S donors have been reported with various conditions enabling release. Building on this work, the development of polymeric H2S donors with tunable release rates will enable investigation into the complex behavior of H2S in the body. The first half of this dissertation focuses on the design and synthesis of two polymeric H2S donor systems for the controlled release of H2S. These systems take advantage of sequestering the H2S donating species inside a polymeric nanostructure in water called a micelle. Because H2S release requires a triggering molecule to enter the polymeric nanostructure, release rate can be tuned by modifying the mobility of the structure. The first system discussed demonstrates this concept by increasing the flexibility of the micelle core. As expected, H2S release rates increased with increasing flexibility. The second system discussed advances this idea by limiting mobility within the micelle core, rather than increasing flexibility. Accordingly, H2S release rates decreased with decreasing mobility within the micelle core. The latter half of this dissertation broadly explores the development of polymeric signaling gas delivery vehicles with triggered release conditions. We first investigate the impact of polymer chain flexibility on the formation of micelles in water. Polymer chain flexibility significantly impacted the balance between micelles and unassembled polymer chains in solution, suggesting the need to consider this characteristic when designing donor systems for precise release conditions. Lastly, we discuss the development of controlled polymerization techniques for poly(olefin sulfones). We envision that poly(olefin sulfones) will be a useful class of polymers in the design of donor systems relying on triggered depolymerization for release of the signaling gas sulfur dioxide.

hydrogen sulfide

sulfur dioxide

polymer micelles

drug delivery

Control of swelling, electrochemical, and elongation properties of photopolymers through the modification of structure

McLaughlin, Jacob Ryan

01 May 2018

Modifying photopolymer structure on the molecular and nanoscale level permits tailoring materials for use in a wide variety of applications. Understanding the fundamentals behind polymer structure at these levels permits the control of material properties. This work gains insight into the modification of structure on two levels, the nanoscale by use of structure templates and the molecular scale through the modification of polymer network formation. Lyotropic liquid crystals (LLCs) are a type of self-assembling surfactant system, which in combination with photopolymerization can be used to template ordered nanostructure within polymer materials. This structure can be controlled and utilized to influence the properties of a polymer material. This research examines materials used as templating agents and the types of nanostructures that may be obtained. Additionally, their effects upon the LLC templating process and material properties is determined. Structured polymers are created using LLC templates in pursuit of materials for use in water purification processes and electrochemical devices. Through a more complete understanding of the fundamentals of the templating process, the work presented here extends the LLC templating technique to a greater variety of materials and applications in the water remediation and energy storage fields. The second portion of this research is the use of reversible addition fragmentation chain transfer (RAFT) to modify photopolymer networks. RAFT agents are utilized to control the propagation reaction to create networks with increased homogeneity between network crosslinks. By increasing the uniformity of the polymer network, increases in polymer elongation and toughness as well as decreases in polymer modulus are observed. The effects of RAFT agent addition on the network formation and the final properties of the photopolymer is examined. By understanding the mechanisms behind this modification technique, photopolymers can be extended into new applications where increased elongation and toughness is valued.

forward osmosis

liquid crystals

photopolymerization

stimuli-reponsive material

structure property relationship

Chemical Engineering

Synthese und kolloidale Eigenschaften neuartiger Blockcopolymere mit beta-Dicarbonyl Einheiten = Synthesis and colloidal properties of a novel type of block copolymers bearing beta-dicarbonyl residues / Synthesis and colloidal properties of a novel type of block copolymers bearing beta-dicarbonyl residues

Krasia, Theodora

January 2003

The present work is dealing with the first synthesis and characterisation of amphiphilic diblock copolymers bearing b-dicarbonyl (acetoacetoxy) chelating residues. Polymers were obtained by Group Transfer Polymerisation (GTP)/acetoacetylation and controlled radical polymerisation techniques (RAFT).<br><br>Different micellar morphologies of poly(n-butyl methacrylate)-block-poly[2-(acetoacetoxy)ethyl methacrylate] (pBuMA-b-pAEMA) were observed in cyclohexane as a selective solvent. Depending on the block length ratio, either spherical, elliptical, or cylindrical micelles were formed. The density of the polymer chains at the core/corona interface is considerably higher as compared to any other strongly segregating system reported in the literature. It is demonstrated that there are H-bond interactions existing between acetoacetoxy groups, which increase the incompatibility between block segments. In addition, such interactions lead to the formation of secondary structures (such as b-sheets or globular structures) and larger superstructures in the micrometer length scale.<br><br>Block copolymers were also used to solubilise metal ion salts of different geometries and oxidation states in organic media, in which are otherwise insoluble. Sterically stabilised colloidal hybrid materials are formed, i.e. monodisperse micelles having the metal ion salt incorporated in their core upon complexation with the ligating pAEMA block, whereas pBuMA forms the solvating corona responsible for stabilisation in solution. Systematic studies show that the aggregation behaviour is dependent on different factors, such as the tautomeric form of the beta-dicarbonyl ligand (keto/enol) as well as the nature and amount of added metal ion salt.

Chemistry and allied sciences

NMR studies of radical polymerization processes

Klumperman, Bert

12 1900

Thesis (DSc)--Stellenbosch University, 2012. / ENGLISH ABSTRACT: Examples of the use of NMR spectroscopy in the study of radical polymerization processes have been described. The studies presented have made a significant contribution to the understanding of the fundamental mechanistic processes in these polymerization systems. It is pointed out that NMR in conventional radical polymerization is of limited use due to the concurrent occurrence of all elementary reactions (initiation, propagation and termination). Conversely, for living radical polymerization, NMR has great value. In that case, the elementary reactions are somewhat more restricted to specific times of the polymerization process. This allows for example the detailed study of the early stages of chain growth in Reversible Addition-­‐Fragmentation Chain Transfer (RAFT) mediated polymerization. Two different studies are described. The first is related to the early stages of RAFT-­‐mediated polymerization. A process for which we coined the name initialization was studied via in situ 1H NMR spectroscopy. It is shown that in many cases, there is a selective reaction that converts the original RAFT agent into its single monomer adduct. A few different examples and their mechanistic interpretation are discussed. It is also shown that NMR spectroscopy can be a valuable tool for the assessment of a RAFT agent in conjunction with a specific monomer and polymerization conditions. In the second study, 15N NMR, 31P NMR and 1H NMR are used for two different types of experiments. The first is a conventional radical copolymerization in which the growing chains are trapped by a 15N labeled nitroxide to yield a stable product. In the second experiment, a similar copolymerization is conducted under nitroxide-­‐mediated conditions. The nitroxide of choice contains phosphorous, which enables the quantification of the terminal monomer in the dormant chains. Each of the experiments individually provides interesting information on conventional radical copolymerization and nitroxide-­‐mediated copolymerization, respectively. Combination of the experimental data reveals an interesting discrepancy in the ratio of terminal monomer units in active chains and dormant chains. Although not unexpected, this result is interesting and useful from a mechanistic as well as a synthetic point of view. In terms of future perspectives, it is expected that the advanced analytical techniques as described here will remain crucial in polymer science. Present developments in radical polymerization, such as investigations into monomer sequence control, rely on accurate knowledge of kinetic and mechanistic details of elementary reactions. It is expected that such detailed studies will be a main challenge for the next decade of polymer research. / AFRIKAANSE OPSOMMING: Voorbeelde van die gebruik van KMR-­‐spektroskopie in die studie van radikaalpolimerisasies word beskryf. Hierdie studies het ʼn beduidende bydrae gelewer tot die verstaan van die fundamentele meganistiese prosesse in hierdie polimerisasiesisteme. Dit het daarop gewys dat KMR beperkte gebruike het in konvensionele radikaalpolimerisasies as gevolg van die gelyktydige voorkoms van alle basiese reaksies (afsetting, voortsetting en beëindiging). Aan die anderkant het KMR groot waarde vir lewende radikaalpolimerisasie. In hierdie geval is die elementêre reaksies ietwat meer beperk tot spesifieke tye van die polimerisasieproses. Gedetailleerde studies kan byvoorbeeld van die vroeë stadiums van die kettinggroei in Omkeerbare Addisie-­‐Fragmentasie-­‐ KettingOordrag (OAFO)-­‐bemiddelde polimerisasie gedoen word. Twee verskillende studies is beskryf. Die eerste het betrekking op die vroeë stadiums van die OAFO-­‐bemiddelde polimerisasie. 'n Proses wat “inisialisering” genoem is, is bestudeer deur middel van in situ 1H KMR-­‐spektroskopie. Dit is bewys dat daar in baie gevalle 'n selektiewe reaksie is wat die oorspronklike OAFO-­‐agent in sy enkelmonomeeradduk verander voor polimerisasie. 'n Paar ander voorbeelde en hul meganistiese interpretasie is bespreek. Dit is ook bewys dat KMR-­‐spektroskopie 'n waardevolle hulpmiddel kan wees vir die assessering van 'n OAFO-­‐agent in samewerking met 'n spesifieke monomeer en polimerisasie toestande. In die tweede studie is 15N KMR, 31P KMR en 1H KMR gebruik vir twee verskillende tipes van die eksperiment. Die eerste is 'n konvensionele radikaalkopolimerisasie waarin die groeiende kettings vasgevang word deur 'n 15N-­‐gemerkte nitroksied om 'n stabiele produk te lewer. In die tweede eksperiment is 'n soortgelyke kopolimerisasie gedoen onder nitroksied-­‐ bemiddelde toestande. Die gekose nitroksied bevat fosfor wat die kwantifisering van die terminale monomeer in die dormante kettings moontlik maak. Elkeen van die individuele eksperimente lewer interessante inligting oor konvensionele radikale kopolimerisasie en nitroksied-­‐bemiddelde kopolimerisasie, onderskeidelik. ʼn Kombinasie van die eksperimentele data toon 'n interessante verskil aan in die verhouding van die terminale monomeereenhede in die aktiewe en sluimerende kettings. Alhoewel dit nie onverwags is nie, is die resultate interessant en van waarde vanuit 'n meganistiese-­‐ sowel as 'n sintetiese oogpunt. In terme van toekomstige perspektiewe word daar verwag dat gevorderde analitiese tegnieke soos hier beskryf, belangrik sal bly in polimeerwetenskap. Huidige ontwikkelinge in radikaalpolimerisasie, soos ondersoeke na die beheer van monomeervolgorde, maak staat op akkurate kennis van kinetiese en meganistiese besonderhede van die basiese reaksies. Daar word verwag dat sulke gedetailleerde studies ʼn uitdaging sal bied vir die volgende dekade van polimeernavorsing.

Nuclear magnetic resonance spectroscopy

Radical polymerization

Nitroxide

Dissertations -- Polymer science

Theses -- Polymer science

Chemistry and Polymer Science

Synthèse, caractérisation et polymérisation par ouverture de cycle par métathèse de macromonomères cyclobuténiques obtenus par chimie " click " et polymérisation RAFT

Le, Dao

20 September 2012

Ce travail de thèse porte sur la synthèse de copolymères greffés à squelette 1,4-polybutadiène (PBu) et polyoxanorbornène par combinaison de ROMP et chimie click et/ou polymérisation RAFT selon la méthode grafting through. Une gamme de macromonomères symétriques et non symétriques originaux poly(oxyde d'éthylène) (POE), poly(acrylate d'éthyle), poly(acrylamide de N-isopropyle) (PNIPAM) et POE-b-PNIPAM ont été synthétisés à partir de précurseurs oxanorbornène et cyclobutène fonctionnalisés présentant un ou deux groupements clickables et/ou un agent RAFT par chimie click et polymérisation RAFT. Une série de PBu-g-POE et polyoxanorbornène-g-POE bien définis ont été obtenus par ROMP en solution en utilisant des amorceurs de Grubbs et de Schrock. Les tests de ROMP en milieu aqueux dispersé ont montré que la mini-émulsion était efficace pour la polymérisation des macromonomères POE à extrémité cyclobutényle et oxanorbornényle.

[CHIM:OTHE] Chemical Sciences/Other

Copolymères greffés

1

4-Polybutadiène

Polyoxanorbornène

" Grafting through "

Chimie " click "

Polymérisation RAFT

ROMP

Synthesis of New lonic Functional Polymers by Free Radical Polymerization via the RAFT Process

Baussard, Jean-François

26 January 2004

Within the emerging methods of controlled free radical polymerization, the Reversible Addition-Fragmentation chain Transfer (RAFT) process has been recently established as a powerful technique to synthesize standard polymers with controlled characteristics (narrow polydispersity and predictable molar masses). This method is now employed to synthesize well-defined, reactive precursor polymers that are subsequently converted into speciality polymers such as fluorescent-labeled polycations. Those are suitable for Electrostatic Self-Assembly (ESA). The observation of the Förster Resonance Energy Transfer (FRET) in such films is established, contributing to the understanding of the self-organization during thin film growth. The RAFT process using Benzyl Dithiobenzoate (BDTB) is shown to enable the control of the free radical polymerization of vinylbenzyl chloride (VBC). The high tolerance of the method to functional groups allows the preparation of such reactive polymers with narrow polydispersities and predictable molar masses. The well-defined precursors are easily converted, for instance, to polycations. Also they are easily functionalized by fluorophores, here derived from coumarin and perylene. The fluorophores, as pendent side chains, served as label to investigate the alternating deposition process, while the influence of molecular variations on the self-assembly can be systematized. Furthermore, when using complementary fluorophores, Fluorescence Resonance Energy Transfer (FRET) studies in organized media become possible. The alternating deposition cycles are followed by UV-Vis spectroscopy, ellipsometry, and X-Ray reflectivity. Regular growth is observed for three complementarily labeled polycations. Noteworthy, fluorescence and UV-Vis studies reveal the formation of large fluorescent dye aggregates for one coumarin and for the perylene derivative in the ESA multilayers. When these polycations are used in mixed thin films, Förster Resonance Energy Transfer (FRET) between fluorophores is observed. The non-radiative nature of the different energy transfer was confirmed by fluorescence decay time measurements/ Parmi les récentes méthodes pour contrôler la polymérisation radicalaire, le procédé RAFT (Reversible Addition-Fragmentation chain Transfer) a été récemment établi et s'impose comme une méthode performante pour la synthèse de polymères standards possédant des caractéristiques contrôlées (faibles polydispersités et masses molaires prédictibles). Cette méthode est désormais utilisée pour la synthèse de précurseurs réactifs bien définis qui sont par la suite convertis en polymères spécialisés, par exemple en polycations marqués a l'aide de sondes fluorescentes. Ces polycations peuvent être ensuite auto-assemblés électrostatiquement afin d'élaborer des films minces. Le phénomène de transfert de fluorescence (Förster Resonance Energy Transfer –FRET-) dans de tels films a été établi, contribuant par là-même à une meilleure compréhension du phénomène d'auto-organisation durant la croissance des films. Le procédé RAFT, utilisant le dithiobenzoate de benzyle (BDTB), a démontré sa capacité à contrôler la polymérisation radicalaire du chlorométhlstyrène (VBC). La tolérance de cette méthode vis à vis des groupes fonctionnels permet la synthèse de polymères réactifs possédant de faibles polydispersités et des masses molaires prédictibles. Les précurseurs ainsi définis sont facilement convertis, en polycations par exemple. Ils sont tout aussi facilement fonctionnalisés par des fluorophores dérivés de la coumarine ou du pérylène. Les fluorophores en tant que chaînes pendantes servent de marqueurs pour étudier le processus de dépôts alternés, alors que l'influence des variations au niveau moléculaire peut être systématisée. De plus, en utilisant des fluorophores complémentaires, il devient possible de mener des études sur le transfert de fluorescence (FRET) au sein de milieux organisés. Les cycles de dépôts alternés ont été suivis par spectroscopie UV-Vis, éllipsométrie et reflexion des rayons X. Une croissance régulière est observée dans le cas des trois polycations marqués. Il convient de noter que les études UV-Vis et de fluorescence révèlent la formation de larges aggrégats de fluorophores au sein des multicouches, dans le cas d'une coumarine et du dérivé de pérylène. Lorsque les polycations complémentaires sont utilisés dans des films minces mixtes, le FRET est observé. La nature radiative ou non-radiative du processus de transfert d'énergie a été confirmée par des mesures de déclin de fluorescence.

Layer-by-Layer (LbL) assembly

Controlled free radical polymerization

Novel synthetic approaches for fabrication of polymer brushes on gold surfaces via Raft polymerization: A new era for gold modification

Catli, Candan

15 February 2017

No description available.

540

Raft polymerization

Polymer brushes

Star polymer

Controlled Radical Polymerization

grafting from

Chemie  (PPN62138352X)

Synthesis, Characterization and High-throughput Screening of Photoiniferter/RAFT Agent for Well-controlled Radical Polymerization of Block Copolymers

Sidi, Zhao

25 June 2019

No description available.

Polymer Chemistry

Polymers

Controlled Radical Polymerization

Photoiniferter

Block Copolymer

3D Printing

Combinatorial High-throughput Screening