24 search hits
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Soft Compartmentalized Polymer Colloids: Janus Particles, Multicompartment Structures, Inorganic-Organic Hybrids and Applications
(2008)
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Andreas Walther
- Compartmentalized polymer-based colloids with nanoscopic dimensions and different topologies were prepared based on various block copolymer architectures. The polymers were prepared via anionic polymerization or a controlled radical polymerization technique (RAFT). Self-assembly both in solution and in bulk were rigorously exploited to create the multicompartment architectures. Several new crosslinking strategies, in bulk and in solution, were thoroughly investigated to allow a controlled preservation and a high shape-persistence of the colloidal particles even when exposed to non-selective solvents. Cylindrical and disc-like Janus particles were investigated according to their self-assembly behavior into superstructures. The Janus discs undergo back-to-back stacking in organic solvent. In aqueous solution, a size-dependent aggregation was found. While the smaller Janus discs are unimolecularly dissolved with a significant polystyrene surface exposed to the water, the larger Janus sheets can shield the insoluble side by a large bending in an intramolecular fashion. Janus cylinders self-assemble on two hierarchical levels. Upon exposure to a selective solvent, they self-organize into fibers. The length of these fibers depends on the concentration and a critical aggregation concentration exists below which self-assembly is absent. Secondly, the Janus cylinders form fibrillar networks with tunable pore sizes when deposited from more concentrated solution. The surface-active properties of spherical Janus particle were exploited for the investigation of two possible applications of both academic and industrial relevance. In Pickering emulsion polymerization, extremely well-defined latexes with long-term stability could be prepared in a very facile fashion. A control of the particle size by changing the concentration of Janus particles could easily be achieved. Secondly, the nanostructuring of polymer blends was shown for a PS/PMMA model system. The system exhibits a control on two length scales. The first is the controlled decrease of the domains of the dispersed phase and the second is the controlled spacing between the particles at the interface. The particles are exclusively located at the interface and the nanostructuring can be obtained while matching macroscopic processing constraints, i.e. high-shear blending in a mini mixer. The self-assembly of bis-hydrophilic triblock terpolymers with two outer hydrophobic blocks was investigated for a variety of different hydrophilic end blocks. The overall architecture of the solution structures could be tailored by changing the hydrophobic-to-hydrophilic balance. Additionally, the interaction between the corona-forming blocks has an influence on the particle shapes as well. The micelles possess coronas with appealing and tunable properties, due to the presence of a hydrophobic core and hydrophilic biocompatible and stimuli-responsive segments. The self-assembly of miktoarm star terpolymers, bearing arms of polystyrene (PS), polybutadiene (PB) and poly(2-vinylpyridine) (P2VP), was analyzed both in solution as well as in the bulk state. In solution, the miktoarm star terpolymers form multicompartment micelles with a glassy (PS) and a soft compartment (PB), all rendered water-soluble by the P2VP corona. Strikingly, the soft PB compartments show hydrophobic bridges in aqueous medium which is of high interest as they can be used as a second motif for sensing, adhesion control or interaction with cellular membranes. The transfer of a hexagonally ordered cylindrical bulk phase via crosslinking of the PB domain of a bulk structure of a similar miktoarm star terpolymer allowed the preparation of novel multicompartment cylinders. The structures possess perfectly parallel aligned compartments. Two symmetric and opposing PS and P2VP compartments surround a central ribbon-like PB compartment. The P2VP compartments could be used to generate perfectly aligned bi-axial nanowires inside spatially separated compartments within close proximity. Due to the presence of an amphiphilic corona, the extent of the compartmentalization can be tuned from separated nanowires into one homogenous nanowire simply by exchanging the solvent. The complexity and high control of the structure of this multicompartment cylinder is unmatched and can most likely not be obtained by solution based self-assembly.
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Ausrichtung von Blockcopolymerfilmen im Elektrischen Feld: Eine In-Situ Rasterkraftmikroskopische Untersuchung
(2007)
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Violetta Olszowka
- Im Rahmen dieser Arbeit wurde die Reorientierung sowohl von dünnen als auch dicken Diblockcopolymerfilmen mit lamellarer Mikrodomänenstruktur im realen Raum untersucht. Die Experimente erfolgten unter Tempern im Lösungsmitteldampf im planaren elektrischen Feld. Es wurden zwei Wege gezeigt, wie lamellare Mikrodomänen aufgestellt und durch ein elektrisches Feld in drei Dimensionen ausgerichtet werden können. In beiden Fällen wurden periodische und hochgeordnete Streifenstrukturen erhalten. Sowohl der Reorientierungsmechanismus der Mikrodomänen als auch der Einfluss des elektrischen Feldes auf die Defektbeweglichkeiten im dünnen Film, wurden mit einem modifizierten AFM, dem so genannten quasi in-situ AFM untersucht. Der Mechanismus der Reorientierung im dicken Film wurde durch eine kombinierte Studie aus AFM, GISAXS, REM und in-situ Ellipsometrie ermittelt. Weiterhin wurden der Verlauf der elektrischen Feldlinien und die Feldstärke für die verwendete Elektrodengeometrie auf der Basis der Finiten-Elemente-Methode simuliert. Ferner wurde der Einfluss des elektrischen Feldes auf den Grad der Ausrichtung für die Polymere SHM und SV untersucht. Hierfür wurden kombinatorische Experimente mit Elektroden in Gradientengeometrie durchgeführt.
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Orientation and Phase Behavior of Block Copolymers in External Electric Fields
(2007)
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Kristin Schmidt
- The influence of external electric fields on the microdomain structure of block copolymers has been studied. The results range from an analysis of the mechanism and kinetics of the reorientation process, via the discussion of the driving force, to first investigations on the influence of an electric field on the phase behavior. The electric field induced effects on concentrated block copolymer solutions were investigated by in-situ synchrotron small-angle x-ray scattering. The first part concerns the analysis of the mechanism and kinetics of the alignment of lamellar forming diblock copolymer solutions as well as a quantitative study of the reorientation kinetics of various block copolymers in order to clarify the driving force of reorientation in a DC electric field. The second part of this thesis describes the influence of an electric field on the phase behavior of block copolymers. It is shown that a gyroid phase (G) as well as a hexagonally perforated lamella phase (HPL) exposed to an electric field undergo a phase transition to cylinders (C) and lamellae (L), respectively. Furthermore, an anisotropic deformation of the chain conformation in various lamellar and cylindrical block copolymer solutions via electric fields is demonstrated.
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New Double-Responsive Micelles of Block Copolymers Based on N,N-Diethylacrylamide: Synthesis, Kinetics, Micellization, and Application as Emulsion Stabilizers
(2005)
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Xavier André
- Thermo- and pH-responsive block copolymers based on (meth)acrylic acid and N,N-diethylacrylamide were synthesized and their aqueous solution behavior was studied. Such bishydrophilic block copolymers represent an interesting class of stimuli-responsive water-soluble materials whose macroscopic properties can be triggered at the molecular level by tuning the temperature, the pH and the ionic strength of the solution. A new method was introduced for the synthesis of well-defined poly(N,N-diethylacrylamide) (PDEAAm) via living anionic polymerization using ethyl alpha-lithioisobutyrate (EiBLi) in the presence of triethylaluminium (Et3Al) as Lewis acid in tetrahydrofuran (THF) at -78 °C. Kinetic investigations were performed using in-situ Fourier-transform Near-Infrared (FT-NIR) fiber-optic spectroscopy. This is the first mechanistic study of the anionic polymerization of a dialkylacrylamide. The polymerization follows first order kinetics with respect to the effective concentration of active chains, [P*]0, but shows complex kinetics with respect to the actual monomer and initial aluminum concentrations. Upon addition of Et3Al, the polymerization rate constant, kp decreases, which is explained by the formation of an amidoenolate chain end/Et3Al complex of lower reactivity. It involves two equilibria: between noncoordinated and Et3Al-coordinated chain ends (deactivation of chain ends) as well as between free and Et3Al-activated monomer (activated monomer mechanism). These two effects are in a delicate balance that depends on the ratio of the concentrations of Et3Al, monomer, and chain ends. Thus, the polymerization rate of this system is governed simultaneously by the complex interplay between the activation of monomer (dependent on monomer and Et3Al concentrations) and the deactivation of chain ends (dependent on the ratio of concentrations of Et3Al to initiator). Polymers with narrow molecular weight distribution are obtained, indicating that the rate of interconversion between the different chain end species is greater than the polymerization rate. In contrast, such well-defined polymers are not found in the absence of Et3Al. PDEAAm polymers, synthesized using organolithium initiator in the presence of Et3Al, are rich in heterotactic (mr) triads and exhibit Lower Critical Solution Temperatures (LCST) in water with a cloud point at Tc = ca. 31 °C. By extending this synthetic concept and using poly(tert-butyl acrylate)-Li, and poly(tert-butyl methacrylate)-Li as macroinitiators, well-defined poly(tert-butyl acrylate)-block-PDEAAm, and poly(tert-butyl methacrylate)-block-PDEAAm block copolymers were obtained. Although the blocking efficiencies remained below 70 % a separation of block and homopolymers was easily possible. The narrowly distributed (AA)45-b-(DEAAm)360 block copolymer obtained after hydrolysis of the protecting tert-butyl groups exhibits interesting ‘schizophrenic’ micellization behavior in response to temperature, to pH, and to ionic strength of the aqueous media. Due to its asymmetric composition, two opposite micellar structures are expected. Indeed, the existence of different micellar aggregates, i.e., ‘crew-cut’ micelles with a PDEAAm core and inverse star-like micelles with PAA core, was proven by several analytical techniques, like Small-Angle Neutron Scattering (SANS), Dynamic and Static Light Scattering (DLS, SLS) and Cryo Transmission Electron Microscopy (cryo-TEM). Furthermore, all the transitions were found to be reversible. Finally, the synthesized bishydrophilic block copolymers were used for batch emulsion polymerizations of styrene, methyl methacrylate and n-butyl acrylate. In all cases, latexes with remarkable long-term stabilities were obtained, which is a very interesting feature from the colloidal point of view. The stabilization efficiency was found to be essentially adjustable by the pH due to the loss of the PDEAAm segment inside the latex particle. A detailed analysis of the particle size and particle size distribution was carried out using a variety of methods, including DLS, TEM and Asymmetric Flow Field-Flow Fractionation (AF-FFF).
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Phasenverhalten von Blockcopolymeren und deren Wechselwirkung mit normalen Kohlenwasserstoff-Tensiden
(2005)
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Elham Eghbali
- Die Mizellbildung dreier Blockcopolymer-Systemen in Wasser und deren Wechselwirkungen mit normalen Kohlenwasserstoff-Tensiden wurden durch Messungen der Oberflächenspannung, Elektronenmikroskopie, Lichtstreuung und Kleinwinkelneutronenstreuung untersucht. Für das System PEO18-PEB64-PEO18 sind die wässrigen Lösungen der Blockcopolymere trüb und metastabil und trennen sich innerhalb von ein paar Wochen in zwei Phasen. Das Blockcopolymer ist oberflächenaktiv und erniedrigt die Oberflächenspannung von Wasser. Die elektronenmikroskopischen Aufnahmen einer 1% igen Lösung des Blockcopolymers in Wasser weisen auf eine Polymorphie der Aggregate und einen fehlenden Gleichgewichtszustand hin. Unilamellare und multilamellare Vesikel und fadenförmige Mizellen sind nebeneinander auf den Aufnahmen erkennbar. Mit der Zugabe eines anionischen Tensids, SDS, ändern sich die optischen Eigenschaften sowie die Nullviskosität der Lösung und die Morphologie der Aggregate. Unterhalb der cmc des Blockcopolymers wurde keine Wechselwirkung mit Tensiden erkannt. Oberhalb der cmc lagern sich die Tensidmoleküle an die Aggregate der Blockcopolymere an. Mit zunehmender Tensidkonzentration verschwinden die größeren Aggregate und Vesikel und die Trübung der Lösung nimmt ab. Die dominante Morphologie ändert sich mit der zunehmenden Tensidkonzentration von Vesikeln zu fadenförmigen Mizellen, zu großen Mischaggregaten und zu kleinen SDS-Mizellen in welche einzelne Polymerketten gelöst sind. Diese Mischmizellen befinden sich im Gleichgewicht mit reinen SDS-Mizellen. Bei Sättigung der Blockcopolymere mit Tensid bleibt die Oberflächenspannung konstant und bei einem Wert wie dem von reinem Tensid. Die Lösungen sind dann klar und haben eine niedrige Viskosität. Die Sättigungs-Tensidkonzentration nimmt linear mit der Polymerkonzentration zu. Für das System PnBA100-PAA150 sind die wässrigen Lösungen der Blockcopolymere trüb und trennen sich in zwei Phasen. Mit der Neutralisation der Polysäure-Gruppe nimmt die Trübung ab. Für dieses System wurden zwei interessante Eigenschaften beobachtet: 1- Keine Oberflächenaktivität 2-Abhängigkeit der Viskosität von dem alpha-Wert Auf den elektronenmikroskopischen Aufnahmen sind die Änderungen der Morphologie und der Teilchenanordnung mit dem alpha-Wert erkennbar. Bei alpha=0 koexistieren unterschiedliche Morphologien wie kugelförmige Mizellen und Stäbchen, deren Größe und Form darauf hinweisen, daß das System sich nicht in einem thermodynamischen Zustand befindet. Bei alpha>0.1 sind die Teilchen ausschließlich kugelförmig. Die Polymer-Moleküle aggregieren in kugelförmige Aggregate mit einer Kern-Schale Struktur. Mit zunehmendem alpha-Wert erkennt man eine hohe Ordnung der Aggregate und einen ziemlich gleichmässigen Abstand zwischen den Teilchen. Die Polyelektrolyt-Kette streckt sich mit zunehmendem alpha-Wert, bei alpha=0,5 hat sie die höchste Länge erreicht und die Mizellen besitzen die höchste Ordnung. Aus der SANS-Messung läßt sich zwischen den Teilchen ein Abstand von ca. 104 nm und ein Durchmesser von ca. 99 nm für die Teilchen berechnen. Dies entspricht einer dichten Packung der Aggregate, welche sich in der hohen Viskosität der Lösung wiederspiegelt. Sowohl kationische, anionische und zwitterionische Tenside lagern sich an das Blockcopolymer an. Das kationische Tensid bindet an die negativ geladenen Säuregruppen und bildet einen nicht löslichen Komplex, welcher sich bei niedrigeren Tensidkonzentrationen um den Kern der Blockcopolymere legt. Die Mizelle hat dann einen schalenförmigen Aufbau mit dem Butylacrylat-Block im Zentrum, der mit einer Schale von dem unlöslichen Komplex umgeben ist. Der Rest der Polyelektrolyt-Kette bildet die Corona.) Bei höheren Tensidkonzentrationen fällt der Komplex aus der Lösung. Das Tensid bindet sich kooperativ an die Polysäure und ist nicht gleichmäßig verteilt. Mit dem anionischen Tensid SDS dominieren hydrophobe Wechselwirkungen. Das Tensid dringt in den Kern der Mizelle hinein. Nach Absättigung der vorhandenen Grenzfläche und Auflösung der Blockcopolymermizellen aggregieren die Tensid-Moleküle in normale Mizellen. Mit dem zwitterionischen Tensid C14DMAO wird die Wechselwirkung bei niedrigen alpha-Werten durch Protonenübertragung und elektrostatische Kräfte und bei höheren alpha-Werten durch hydrophobe Kräfte beherrscht. Das Blockcopolymer PMMA60-PAA90 aggregiert in Wasser ohne die Oberflächenspannung zu erniedrigen. Die wässrigen Lösungen von PMMA60-PAA90 schäumen obwohl das Blockcopolymer die Oberflächenspannung des Wassers kaum ändert. Die Viskosität von 1 %igen Blockcopolymer-Lösungen ändern sich nur wenig mit dem alpha-Wert und bleiben für den ganzen Neutralisationsbereich niedrig. Auf der Kryo-TEM Aufnahme der Mizellen ist eine starke Ordnung erkennbar, die aber keine hohe Viskosität verursacht. Der Unterschied kann ebenfalls an der Länge der Polyelektrolyt-Ketten liegen.
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Holographische Datenspeicherung in nanostrukturierten azobenzolhaltigen Polymeren
(2006)
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Michael Häckel
- In der vorliegenden Arbeit werden verschiedene Diblock-Copolymere mit azobenzolhaltigen Seitenketten auf ihr Potential für Anwendungen als wiederbeschreibbares Medium für die holographische Datenspeicherung untersucht. Die Seitenketten dieser Polymere können durch Bestrahlung mit Licht angeregt und umorientiert werden. Infolge der Anisotropie der Seitenketten führt die Umorientierung in den beleuchteten Bereichen des Materials zu Doppelbrechung und damit zu einer räumlichen Brechungsindexmodulation für polarisiertes Licht. Bei Blockcopolymeren tritt Mikrophasenseparation auf. Diese ermöglicht im räumlichen Mittel eine Verdünnung der Azobenzolfarbstoffe bei gleichbleibend hoher lokaler Konzentration in den eingeschlossenen Minoritätsphasen. Die makroskopische Verdünnung ist zur Reduzierung des Absorptionskoeffizienten notwendig, damit das zum Schreiben verwendete Licht Proben mit einer Dicke im Bereich von 1 mm durchdringen kann. Eine hohe lokale Konzentration ist andererseits für die Stabilisierung der eingeschriebenen Information notwendig. Es ist bekannt, dass in azobenzolhaltigen Homopolymeren und statistischen Copolymeren eine stabile Orientierung bei gleichzeitiger schneller lichtinduzierter Umlagerung durch flüssigkristalline Phasen erreicht werden kann. Um festzustellen, ob die kooperative Umorientierung der Seitenketten und ihre gegenseitige Stabilisierung auch in den Minoritätsphasen von Blockcopolymeren auftreten, wurden solche Blockcopolymere untersucht, die in den Seitenketten des photoadressierbaren Blocks methoxysubstituierte Azobenzolgruppen und nichtabsorbierende Dreikernmesogene in unterschiedlichem Verhältnis enthielten. Mit zunehmendem Anteil der mesogenen Seitenketten stieg trotz des gleichzeitig abnehmenden Anteils der Farbstoffgruppen die erreichbare Brechungsindexmodulation eingeschriebener holographischer Gitter an. Damit konnte gezeigt werden, dass sich auch in Blockcopolymeren die mesogenen Seitenketten gemeinsam mit den Farbstoffgruppen umorientieren lassen. Mit steigendem Mesogenanteil stieg die Stabilität der eingeschriebenen Gitter ebenfalls an. Ab einem Anteil von 35 mol-% mesogenen Seitenketten im photoadressierbaren Block war diese so hoch, dass innerhalb eines Zeitraumes von zwei Jahren keine Relaxation der eingeschriebenen Orientierung beobachtet wurde. Nachdem an Gittern, deren Dicke wesentlich größer als die Gitterperiode ist, nur dann Beugung auftritt, wenn die Bragg-Bedingung erfüllt ist, können mehrere Hologramme an der selben Stelle des Mediums eingeschrieben und unabhängig voneinander wieder gelesen werden. Dadurch erhält man zu den üblichen zwei Dimensionen eines flächigen optischen Datenspeichers den Winkel als dritten Freiheitsgrad. An 1,1 mm dicken Spritzgussproben von Mischungen aus einem Blockcopolymer und Polystyrol wurden Experimente zum Winkelmultiplexing einfacher holographischer Gitter durchgeführt. Es gelang, sowohl überlagerte Intensitätsgitter als auch überlagerte Polarisationsgitter einzuschreiben. In azobenzolhaltigen Polymeren wächst die Brechungsindexmodulation holographischer Gitter extrem nichtlinear mit der Belichtungszeit an. Dennoch konnten in der Praxis Intensitätsgitter mit gleicher Belichtungszeit eingeschrieben werden, die am Ende der Einschreibvorgänge nahezu identische Beugungseffizienzen aufwiesen. Bis zu 200 holographische Intensitätsgitter konnten an der selben Stelle des Materials erzeugt werden. In Mischungen von Polystyrol mit Blockcopolymeren, die nichtabsorbierende mesogene Seitenketten oder mesogene Farbstoffgruppen enthielten, wurde sowohl bei einzelnen Hologrammen als auch im Fall mehrerer überlagerter Gitter eine sehr gute Stabilität beobachtet. Als nächsten Schritt hin zur Speicherung realer Daten wurden ausgedehnte Hologramme von zweidimensionalen Testbildern gespeichert. Mehrere dieser Hologramme konnten ebenfalls erfolgreich an der selben Stelle unter unterschiedlichen Winkeln geschrieben und rekonstruiert werden. Die Umorientierung von Azobenzolseitenketten ist reversibel. Die Materialien sind daher wiederbeschreibbar. Es konnte ein geeignetes Verfahren entwickelt werden, das es ermöglicht, Hologramme auf rein optischem Wege nahezu vollständig zu löschen und das Medium mehrere tausend Male wiederzubeschreiben. Zum Löschen wurde jeweils ein zweites holographisches Gitter verwendet, das zu dem ursprünglich eingeschriebenen um 180° phasenverschoben war. Dadurch wurde die Information bereits nahezu vollständig gelöscht. Anschließend wurde mit einem einzelnen Laserstrahl, dessen Polarisation um 90° gedreht war, nachbelichtet, um die Farbstoffgruppen wieder in die Polarisationsrichtung der Schreibstrahlen zu orientieren. Durch diese beiden Schritte konnte die Beugungseffizienz der Hologramme um mehr als zwei Größenordnungen abgeschwächt werden und es wurde nach mehr als 1000 Schreib-Lösch-Zyklen wurde weder eine Abnahme der Beugungseffizienz eingeschriebener Gitter noch eine Verschlechterung des Löschverhaltens beobachtet.
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Donor-Acceptor Block Copolymers for Charge Separation at Nanostructured Interfaces
(2006)
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Stefan Lindner
- The motivation for this thesis was the synthesis and characterization of novel materials exhibiting nanostructured interfaces for electro-optical studies. Therefore a series of functionalized block copolymers, acceptor labeled polymers and low molecular weight model compounds were synthesized in which hole transport (donor), electron transport (acceptor) and light absorbing functionalities were incorporated. My approach was to use functionalized block copolymers. Block copolymers exhibit microphase separation with domain sizes on a nanometer scale by the interplay between immiscibility and molecular connectivity. I used a controlled radical polymerization technique, the nitroxide mediated radical polymerization (NMRP), to get block copolymers with one block consisting of an electron transport material and the other one of a hole transport material. Triphenylamine was used as hole conductor in combination with perylene bisimide as dye and electron conductor. First, a soluble perylene bisimide monomer had to be synthesized. This was achieved by an unsymmetrical synthesis starting from the perylene-3,4:9,10-tetracarboxylic bisanhydride. For the solubility a swallow-tail substituent was introduced and the other imide group was functionalized with an acrylate to get the monomer. Starting the polymerization with 4-vinyltriphenylamine, different PvTPA 23 macroinitiators were synthesized. A series of block copolymers 24C-24F were prepared using the same PvTPA macroinitiator 23C, thus only varying the perylene bisimide block. Furthermore, a series of block copolymers 24A-24C were synthesized using different PvTPA macroinitiators 23A-23C. Thus block copolymers with different molecular weights, but similar ratios of the blocks could be prepared. The controlled nature of NMRP allowed the architecture of these block copolymers with low polydispersities and controlled molecular weight. The block copolymers exhibited microphase separation, revealing elongated nanowire like structures for those with high perylene bisimide content. Most of these block copolymers exhibit a constant width of 13 nm for the nanowire like structure of the perylene bisimides. This was the first examples of microphase separation of block copolymers carrying electron transport and hole transport blocks. The electrochemical properties of the block copolymers were studied using cyclic voltammetry. The LUMO of the perylene bisimide block is -3.65 eV and the HOMO of the triphenylamine block is -5.23 eV. Therefore the maximum built-in potential and theoretically achievable photovoltage Voc is 1.58V. The efficiency of the block copolymer solar cells is one order of magnitude higher than that of the comparable blend device. It could also be shown that the block copolymer in the solar cell is microphase separated, revealing domain sizes from 10 to 50 nm, whereas the blend on the other hand is macrophase separated. This is the first report of charge separation at a nanostructured bulk interface in a block copolymer consisting of an electron transport and a hole transport material exhibiting microphase separation. These results are thus proof-of-principle for the nanostructured bulk heterojunction solar cells using block copolymers. Furthermore, fluorescent acceptor labeled polymers were synthesized using a series of monomers in order to obtain a single dye unit attached to various polymer chains. These polymers were prepared by nitroxide mediated radical polymerization with an alkoxyamine initiator that is covalently bound to a perylene bisimide moiety. It could be shown with MALDI-TOF mass spectrometry that a single perylene bisimide unit is incorporated in each polymer chain. By using 4-vinyltriphenylamine monomers bifunctional polymers (8) containing electron donating moieties and a single electron acceptor unit were obtained. The polymerization of standard monomers such as styrene and acrylates, gave polymers (9-12) with only a single electron acceptor unit. Also novel electron acceptors consisting of perylene bisimide and fullerene moieties 15 and 17 were prepared and characterized. Although these dyads do not exhibit any ground state electronic coupling between the individual moieties, the emissive properties of the perylene bisimide units are strongly influenced by the covalently bound fullerene. The fluorescence of the perylene bisimide moiety is quenched by 99 % due to energy and electron transfer between the fullerene and the perylene bisimide. Beside the use as a model system these dyads are also capable of being used in organic solar cells. PCBM, the fullerene derivative which is usually used in polymer solar cells, is barely absorbing light and therefore perylene bisimide functionalized fullerenes may be an alternative as they strongly absorb light in the visible region.
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Shear-induced alignment in block copolymer solutions
(2005)
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Gabi Cantea
- The alignment of the ordered microdomains of block copolymers in solution has been accomplished by using mechanical shear fields. Two pathways to monitore the achievement of aligned structures have been used: rheo-optical and in situ rheo-SAXS methods. The AC diblock copolymer and ABC triblock terpolymer with high molecular weights and different morphologies were synthesized via anionic polymerization and the alignment has been monitored from the solutions of neat AC diblock, ABC triblock and their blend in a non-volatile solvent. Before proceeding to the alignment protocols the thermodynamics of the diblock copolymer solutions has been studied by rheological means. The slightly asymmetric diblock copolymer polystyrene-b-poly(t-butyl methacrylate) (ST) as solutions at different concentrations was investigated by scanning of moduli over a range of temperatures and the morphological transitions were detected. This led us to conclude that dioctyl phthalate is a selective solvent for this diblock copolymer (ST) and a transition from the initially lamellar toward a cylindrical or spherical morphology takes place before order-disorder transition. A route to check the induced asymmetry due to the solvent selectivity was accomplished by applying the Leibler dilution approximation theory. While for the less asymmetric diblock copolymer ST(72K) the dilution approximation theory could be approached, for the higher asymmetric ST(117K) a failure of the theory has been encountered. For the system ST(72K) where the theory was still valid, as a result an expression for the interaction parameter has been developed. The alignment kinetics were performed first by making use of the rheooptical method and the monitored retardation was further used for calculation of birefringence. A perfectly symmetric diblock ST with high molecular weight (100K) as solution in dioctyl phthalate was used for the alignment protocols. Previous investigation of such system did not show any order-order transition, thus for this particular symmetric diblock the same lamellar morphology was preserved in the swollen state. Over a wide range of frequencies and strain amplitudes the monitored birefringence was always positive meaning a perpendicular alignment with the normals of lamellae along the vorticity axis and perpendicular on the plane formed between flow direction and gradient velocity axes. This prefered alignment has been explained due to the low viscoelastic contrast between the polystyrene and poly(t-butyl methacrylate) blocks which did not allow the sliding toward a parallel alignment found for systems with a large viscoelastic contrast. Thus, choosing an appropriate chemical sequence of blocks a selective type of macroscopic alignment by LAOS can be achieved. The introduction of the third elastomeric block between the thermoplastic outer blocks (S and T), namely SBT triblock terpolymer, lead to significant changes in terms of alignment in the sense of tunable intermediate (perpendicular and transverse) aligned states which finally led to the same final parallel orientation in the diluted state. The in situ rheo-SAXS method applied to the same system elucidated the intermediate mechanism leading to a final parallel aligned state such as a coexistence of parallel and perpendicular states which gave rise to a transverse alignment in rheooptical method. As a finally aligned state resulting from in situ rheo-SAXS in oscillatory mode the perpendicular one was found within a short time scale (1h), while the rheooptical method revealed a perpendicular state at short time scale (1h) and parallel state at long time scale (10h). Finally, the investigation of the lamellar non-centrosymmetric blend SBT:ST=60:40 allowed preferential parallel alignment above a critical strain amplitude instead below the critical strain amplitude only perpendicular alignment is achieved. While the rheooptical method applied to a bcc morphology of a solution of SBM triblock terpolymer in DOP did not give evidence for an induced morphological transition, in situ rheo-SAXS was a powerful tool to illustrate such a transition. Moreover, we have shown that more complicated morphologies like knitting pattern of SEBM (as cast film from chloroform) which reveals a bcc morphology as a solution in DOP could be investigated and macroscopically aligned via in situ rheo-SAXS while the rheooptical method could not be used due to the non transparent system. The induced columnar structure could be monitored in 2D SAXS patterns which have never been reported before. In summary, it was demonstrated that mechanical field alignment of block copolymer domains in solution allowed to generate highly anisotropic structures even for block copolymers with high molecular weights under ambient conditions and for a large variety of morphologies.
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Structural Analysis of Cylindrical Particles by Small Angle X-ray Scattering
(2005)
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Li Li
- The objective of this work is to analyze nano-scaled cylindrical particles by small angle X-ray scattering (SAXS). Three systems with cylinder-shaped particles: (1) Laponite particles in aqueous solutions, (2) Poly(carbon suboxide) particles in binary water/DMF solutions, and (3) Suprastructural aggregates of coil-ring-coil block copolymers in cyclohexane, have been studied by SAXS performing either a Kratky-Compact-Camera in our laboratory or ID2 beamline of the European Synchrotron Radiation Facility (ESRF) in Grenoble. The synthetic clay particles, Laponite RD, have been chosen as ideal disc-shaped model particles. In combination of SAXS with static light scattering, the scattering intensities of a concentration serial (volume fraction from 0.0002 to 0.0016) were measured in almost three orders of magnitude of the scattering vector q. Through extrapolation of concentration the scattering intensity at vanishing concentration, i.e. the form factor P(q) of particles was achieved. It shows q-2 decay at intermediate q range, which indicates that the shape of single Laponite particle in aqueous solution is platelet. The plateau of the form factor at low q range implies that there is no aggregate or cluster structure, and the Laponite particles are dispersed completely under the investigated conditions. More detailed structural information was then obtained by fitting of P(q) with disc model. The radii of the discs exhibit a large polydispersity. A radius of 10.5 nm with Schulz-Zimm distribution of Rw/Rn = 1.5 (where Rw and Rn denote weight and number average radius, respectively) was found to fit the form factor perfectly. The thickness of one single platelet was determined to be 0.9 nm. The weight averaged molecular weight and radius of gyration were determined to be 930 kg/mol and 13.4 nm, respectively. The inter-particle interactions of Laponite particles were investigated by the structure factor S(q), from which the effective diameter of interparticle interactions deff was determined for the first time. The strong electrostatic Coulomb repulsion between charged Laponite particles was attributed to the much higher value of deff (= 46 nm), in comparison to 2Rg (= 27 nm). The recently developed multicomponent interaction site model was performed by Harnau to predict these experimental structure factors. An effective potential of interaction, which pays attention to a screened Coulomb interaction as well as an attractive interaction, leads to the best description of the model to the experimental data. By means of SAXS, the size of synthetic polymer carbon suboxide ((C3O2)n) dissolved in binary water/DMF solutions was determined for the first time with radius of gyration Rg = 1.7 nm and molecular weight Mw = 2760 g/mol, which corresponds to a polymerization’s degree of about 40. This value is much larger than literature one (5-10). The form factor of polymer carbon suboxide can be described by a semiflexible chain model. The radius of gyration in cross-section RC and molecular weight per unit length ML were obtained to be 0.3 nm and 350 g/(mol.nm), respectively, which can confirm the fact that the chemical structure of poly(carbon suboxide) is repeated pyronic ring, as suggested in most literatures. Thus the structure and size of polymer carbon suboxide were characterized completely by SAXS. Finally, SAXS was employed to analyze a suprastructural aggregation system derived by self-assembly of coil-ring-coil block copolymers. This is a newly synthesized subclass of rod-coil block copolymers composed of a nanometer-sized shape-persistent macrocycle and two covalently attached polystyrene (PS) coils. The solubility of the rigid ring is largely enhanced due to the attachment of the flexible side groups. With suitable length of the flexible side groups (Mw (PS) = 2500 g/mol) the block copolymers can form colloidal-sized aggregates in selected solvent cyclohexane, which were concluded to be of cylindrical shape with the rigid rings packing densely in a tubular way and the flexible side groups arranging outside of the ring. Such aggregated cylinder brushes can be further confirmed to exist as a mixture of cylinder bundles by analyzing the local structural parameter ML (= 25730 g/(mol.nm), molecular weight per nm length of cylindrical objects). In comparison of this value with M0 (= 6500 g/mol, molecular weight of single coil-ring-coil block copolymer) and d (= 0.6 nm, distance of adjacent densely packed rings), the number fraction of coexisted single cylinder, bi- and tri-cylinder bundles was resulted to be 1:1:2. Through fitting by using approximated circular cylinder model the radius of single cylinders was determined to be 2.6 nm (polydispersity 20 percent) with a hollow inside of radius of 1.2 nm.
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New block copolymers of Isobutylene by combination of cationic and anionic polymerizations
(2004)
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Nemesio Martínez-Castro
- The studies presented in this thesis deal with the new block copolymers of isobutylene by combination of cationic and anionic polymerizations, which are new materials with numerous promising potential applications. A new method for the synthesis of tailored polyisobutylene(PIB)-based block copolymer by combination of controlled / living cationic and anionic polymerizations has been developed. In addition and parallel to these subjects, new synthetic routes for preparation of telechelic PIBs and conductive polymers have been investigated. The PIB precursors used for subsequent anionic polymerization and other processes were prepared by controlled / living cationic polymerization of isobutylene followed by quenching with thiophene under selected conditions. Quantitative functionalization of living PIB with thiophene (T) has been achieved. The process is complicated by coupling between living PIB and PIB-T formed by in situ deprotonation. By lithiation of PIB-T a new, convenient method has been demonstrated for the synthesis of PIB-based block copolymers, involving anionic initiation of tert-butyl methacrylate. A major improvement is that for an industrial process, lithiation by n-BuLi is much more convenient than metalation by Na/K alloy, which had to be used in former processes. Block copolymers with narrow and unimodal molecular weight distribution (MWD) were synthesized under well-controlled conditions. The lithiated thiophene-capped PIB was also used to prepare four-armed star PIB via chlorosilane coupling. Using the same method, new amphiphilic block copolymers, namely PIB-b-poly(N,N-dimethylacrylamide) and PIB-b-poly(ethylene oxide) were synthesized. The anionic polymerization of N,N-dimethylacrylamide (DMAAm) was carried out with a binary initiator system prepared from thienyllithium and the Lewis acids triethylaluminium (Et3Al), diethylzinc (Et2Zn) or triethylborane (Et3B) in THF. Polymerizations proceeded in a homogeneous manner and gave polymers having controlled molecular weights. However, in presence of alkoxides the polymerization results in polymers insoluble in THF, even using Et3Al. Finally, lithiated PIB-T, in conjunction with Lewis acids, was used to initiate the living anionic polymerization of DMAAm, resulting in the new amphiphilic block copolymer PIB-b-PDMAAm. The anionic polymerization of ethylene oxide (EO) was carried out with a binary initiator system prepared from thienyllithium and the polyiminophosphazene base tBu-P4 in THF. Lithilated PIB-T- in conjunction with tBu-P4 was used to initiate the living anionic polymerization of ethylene oxide. In a second method, PIB-b-PEO was synthesized using hydroxyl end-capped PIB as macroinitiator in conjunction with tBu-P4. The aggregation behavior in dilute aqueous solutions of a PIB-b-PEO copolymer, produced from the combination of cationic and anionic polymerizations, was investigated by dynamic light scattering in aqueous solution. The monoaddition of ethylene oxide to lithiated PIB-T is demonstrated as a new pathway for the synthesis of hydroxy-functional PIB (PIB-OH). This is a useful alternative to the tedious procedures used in the literature so far. PIB-OH was successfully used as a macroinitiator for the ring-opening polymerizations of L-lactide and epsilon-caprolactone catalyzed by stannous octoate. Combination of chromatographic methods and MALDI-TOF ass spectrometry gave information about the side reactions during polymerization. Quantitative functionalization of living PIB with 2-bromothiophene has been achieved. Using various coupling methods, this polymer was convertet to a macromonomer with a pendant thiophene group, which is accessible in the 1- and 5-position. Oxidative copolymerization with thiophene led to graft copolymers consisting of polythiophene-graft-PIB.
