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Crystalline-core micelles based on triblock terpolymers with polyethylene middle blocks (2012)

Joachim Schmelz

This thesis is focused on the crystallization-induced structure formation of polyethylene containing triblock terpolymers in organic solvents to surface-compartmentalized worm-like crystalline-core micelles (wCCMs). Obtaining profound knowledge of the parameters controlling the self-assembly process allowed the production of a variety of complex one-dimensional micellar architectures with many potential applications, such as adaptive surfactants. At first, the basic parameters that control the crystallization-induced self-assembly were explored using symmetric polystyrene-block-polyethylene-block-poly(methyl methacrylate) (PS-b-PE-b-PMMA) triblock terpolymers and a PS-b-PE-b-PS triblock copolymer. In good solvents for the PE block, e.g. THF and toluene, the selective formation of wCCMs was observed over a wide range of concentration, applied crystallization temperature and polymer composition. Whereas wCCMs produced by PS-b-PE-b-PS showed a homogeneous PS corona, a patch-like compartmentalization of the corona was observed if the micelles were formed by PS-b-PE-b-PMMA. As THF shows equal solvent quality for both corona blocks, wCCMs with almost alternating PS and PMMA compartments of about 15 nm were observed in this solvent. However, if structure formation was conducted in bad solvents for PE, such as dioxane or dimethylacetamide, spherical micelles with amorphous PE cores were formed already before crystallization. Hence, the subsequent crystallization of PE resulted in spherical CCMs with a patchy or a homogeneous corona depending on the used triblock. These findings allow the highly selective production of stable spherical or worm-like CCMs from the same polymer. As the corona structure of the patchy micelles self-assembled from triblock terpolymers was mainly deduced from transmission electron microscopy (TEM) performed on dried samples, a small-angle neutron scattering (SANS) study was performed in order to elucidate the morphology in solution. Therefore a partly deuterated triblock terpolymer was synthesized and measured at different contrasts to allow the selective detection of the different corona compartments. The resulting SANS curves could be interpreted using a form factor model for core-shell cylinders with alternating PS and PMMA hemishells including interparticle interactions, thus validating the TEM observations. Notably, Janus-type and patchy cylinders can be clearly distinguished using the applied form factor model. Moreover, the controlled formation of wCCMs with tunable corona composition and structure was achieved using the cocrystallization of different triblock copolymers. Via random cocrystallization of PS-b-PE-b-PMMA and PS-b-PE-b-PS the corona morphology could be tuned continuously from a mixed corona at low PMMA content over spherical PMMA patches of increasing number and size to alternating PS and PMMA patches. This approach allows to manufacture wCCMs with predefined corona structure omitting the need to synthesize a new tailor-made triblock terpolymer for every desired morphology. By establishing the controlled crystallization-driven self-assembly of triblock terpolymers with PE middle blocks, it was further possible to prepare wCCMs with predefined average lengths up to 500 nm and length polydispersities as low as Lw/Ln = 1.1. Here, self-assembled spherical CCMs of PS-b-PE-b-PS were used as seeds for the controlled growth of PS-b-PE-b-PS unimers. Upon further addition of PS-b-PE-b-PMMA unimers these grew epitaxially onto the preexisting wCCMs, resulting in triblock co-micelles that consisted of middle blocks with a homogeneous PS corona and outer blocks with alternating PS/PMMA compartments. These structures represent not only the first block co-micelles including blocks with a patchy corona, but also the first ones produced from purely organic block copolymers. In view of application, the ability of patchy wCCMs formed by PS-b-PE-b-PMMA to stabilize interfaces was investigated using pendant-drop tensiometry. The observed reduction of the interfacial tension at the toluene/water interface was significantly higher than that of comparable triblock terpolymer single chains and that of wCCMs with a homogeneous PS corona. Interestingly, the obtained equilibrium interfacial tension equaled that of Janus cylinders with similar dimensions. To explain this unexpected finding the corona chains were proposed to adapt to the interface via selective collapse and shielding of the incompatible part of the corona chains. Studying wCCMs formed by several triblock terpolymers with different compositions, the interfacial activity was found to increase with increasing overall length of the corona chains, and to a certain extent with the molar fraction of PS units in the corona.

Synthesis, Characterization, and Properties of Tailored Functional Block Copolymers (2011)

Robin Pettau

This thesis covers the design, synthesis, characterization, and application of functional block copolymers (BCP) based on a polymer analogous approach and includes three main subjects. The first subject is the implementation of a specially constructed reactor setup for sequential anionic polymerization that allows parallel block copolymer synthesis based on one identical A-block on a lab scale. For this reason, this setup facilitates the preparation of block copolymer series in a combinatorial fashion. It consists of one main reactor and three secondary reactors with individual temperature control. The addition of monomers or additives to each reactor can be handled separately. AB diblock copolymer and ABC triblock copolymer series were prepared with different lengths of the final block as well as different chemical structures of the last block. The second subject covers the synthesis, characterization, processing and application of new liquid crystalline azobenzene-containing block copolymers designed as materials for holographic data storage. Therefore, these polymers contained an amorphous, optical inert poly(methyl methacrylate) (PMMA) or polystyrene (PS) matrix and a functional segment based on polyhydroxystyrene (PHS). Different lengths of flexible spacers and/or mixtures of two spacer lengths were employed to connect the mesogenic chromophores to the polymer backbone. The structure-property relation of functionalized BCPs and the resulting mesophase was investigated. Holographic experiments were conducted on selected examples of the photo-addressable polymers. Smectic annealed samples or amorphous quenched samples were obtained by different sample preparation methods to investigate the influence of the liquid crystalline order. While the initial sensitivity to light induced orientation of the polymer systems remained unaffected, the writing times and level of postdevelopment were improved for quenched samples. Variation in spacer lengths resulted in decreasing smectic order with decreasing spacer length as well as for mixtures of two different spacer lengths promoting lower writing times in the holographic experiments. Additionally, the temperature dependence of the temporal evolution of the refractive index modulation in the smectic polymers was studied. A significant decrease of writing times and an enhancement of the postdevelopment were revealed at elevated temperatures. Stable holographic gratings could be obtained even at 100 °C. 1.1 mm thick samples, that are a prerequisite for volume holographic data storage with a high data storage density, were prepared by injection molding of blends of photoaddressable BCPs with PMMA or PS. Preliminary results confirmed the long-term stability of inscribed holographic gratings and demonstrated angular multiplexing of holographic volume gratings. The third subject covers the synthesis and characterization of new cyanobiphenyl-containing ABA triblock copolymers and their application as BCP gelators for the low molecular weight liquid crystal (LC) 4-cyano-4’-(pentyl)biphenyl (5CB). Based on the selective solubility of the A and B blocks in the nematic solvent, ABA triblock copolymers can be used for the thermoreversible gelation of 5CB. To this end, ABA and ABA’ triblock copolymers comprised of PS A-blocks and a cyanobiphenyl-functionalized PHS B-block with a high degree of polymerization were prepared by the combination of anionic polymerization, using two different synthetic routes, and polymer analogous attachment of the mesogens. Series of linear gelators were prepared with variations in B-block length, A-block lengths and star shaped BCPs by coupling linear ABA’ triblock copolymers. Structure-property relations of the cyanobiphenyl-functionalized polymers regarding the mesophase characterization revealed a dependence of solubility in the nematic 5CB on spacer length. A comprehensive study was conducted to investigate the influence of the BCP backbone and architecture on the gelation of 5CB. Oscillating rheology measurements and thermal characterization were employed to investigate the thermoreversible LC gels. Most of the BCP gelators achieved gelation of 5CB at a mass concentration of 5 wt%. The properties of the different gels where compared at this fixed concentration. The influence of the gelator backbone on the gel properties was investigated by comparing different sets of triblock copolymers. While a short functionalized B-block resulted in high network density and, thus, a high elasticity of the gel the length of the A-blocks influenced the node stability. The LC gel using a star-shaped gealtor exhibited a significantly higher elasticity than with the respective linear block copolymer gelator.

Synthesis of reponsive homo- and block copolymers - application to the generation of inorganic-organic nanohybrids (2010)

Pierre-Eric Millard

Responsive homopolymers and multi-responsive block copolymers were prepared via reversible addition-fragmentation chain transfer (RAFT) and atom transfer radical polymerization (ATRP). Self-assembly in solution depending on environmental stimuli was investigated and exploited to create responsive micelles. New cross-linking strategies were thoroughly performed in aqueous solution to allow a controlled preservation and a high shape-persistence of the colloid particles, even when exposed to non-selective environmental conditions. The synthesis of poly(N-isopropylacrylamide) (PNIPAAm) was investigated by ATRP for subsequent polymer-protein nanohybrid generation. This temperature-responsive polymer was polymerized directly in pure water at a low temperature (4 ºC) by using a functional ATRP initiator which allows post-polymerization conjugation. Without the addition of Cu(II), the kinetics were extremely fast, typically less than one minute for a full conversion. By adjusting the ratio of Cu(I)/(Cu(II) and selecting a very active ligand, all polymerizations proceeded in a controlled fashion to near quantitative conversion without evidence of termination. N-isopropylacrylamide and acrylic acid (AA) were also homopolymerized by RAFT in aqueous media using a novel strategy. Instead of using a diazo-initiator, which generally decomposed at high temperatures, gamma-irradiation was used to initiate polymerization at ambient temperature. This type of radiation has many advantages. A very tiny and constant amount of radicals can be generated, which is perfect for the RAFT process. Moreover, the rate of initiation only has a low level of dependence on temperature and can be used in a wide range of temperatures. Finally, compared to UV-initiation, gamma-irradiation can penetrate the reaction solution deeper and without evidence of irreversible decomposition of the dithioester end group. Therefore, RAFT polymerizations of NIPAAm and AA were achieved with a very good level of control, even at high monomer conversions. This new process was then extended to many other water-soluble monomers for generating homopolymers and block copolymers. Among these, acrylamide, N,N-dimethylacrylamide, 2-hydroxyethyl acrylate and poly(ethylene glycol) methacrylate gave the best results. This technique proved to be very efficient at generating very long and narrowly distributed polymers (up to a degree of polymerization of 10,000) and at designing block copolymers. High molecular weight PNIPAAm-b-PAA copolymers, synthesized by RAFT polymerization under gamma-radiation, were used to generate multi-responsive cross-linked micelles. These block copolymers were self-assembled in water at pH 7 by increasing the temperature over the lower critical solution temperature. The PNIPAAm became hydrophobic and formed the micellar core and the hydrophilic PAA block generated the corona which prevented full aggregation of the system. Then, by amidification at elevated temperatures of the carboxylic moieties via a trifunctional primary amine, the structure was found to remain even after cooling down the system. The shell-cross-linked micelles formed were utilized to generate inorganic-organic nanohybrids by the in situ reduction of gold or silver salts to generate nanoparticles inside the nanocarrier. Another strategy of cross-linking was also investigated by using amino-functional silsesquioxane nanoparticles. In water around neutral pH values and room temperature, these particles interacted with the carboxylic groups of a high molecular weight PNIPAAm-b-PAA by hydrogen bonding and ionic interactions to generate an insoluble complex. Due to the presence of the hydrophilic PNIPAAm block, defined spherical micelles were obtained. The inorganic-organic particles were successfully cross-linked by subsequent amidification to preserve the structure, even at a high pH. Different temperature properties of the hybrids were observed depending on the pH value, due to the residual charge in the micellar core. At a neutral pH, shrinking of the corona was observed, while at a high pH (pH 13) a fully reversible aggregation of the system occurred.

Polymeric Nanoparticles for the Modification of Polyurethane Coatings (2011)

Sandrine Tea

Rubber-based nanomodifiers were successfully synthesized following two different strategies and were used as impact modifiers in polyurethane (PU) automotive clearcoats to improve chip resistance. Various narrowly distributed polybutadiene-b-poly(methyl methacrylate) (B-M) block copolymers differing in composition and molecular weights were synthesized and studied with respect to their self-assembly in organic selective solvents. Dynamic light scattering and transmission electron microscopy measurements revealed that spherical micelles were obtained in acetonitrile for all block copolymers, independently of the polymer concentration. Their radii varied from 11 to 69 nm depending on the molecular weight of the initial linear block copolymer and their aggregation behavior in acetonitrile followed the model established by Förster and Antonietti for strongly segregated block copolymers. In DMF and acetone, block copolymers with 85 %wt PMMA were dissolved as unimers. For lower methacrylate contents, the sizes of the obtained spherical micelles were decreasing from DMF to acetone independently of the polymer concentration. The calculated interaction parameters confirmed acetonitrile as the best solvent for PMMA followed by DMF and acetone as the poorest one. The size of the spherical aggregates could be tuned by the molecular weight and/or by the nature of the selective solvent. Polybutadiene-b-poly(n-butly acrylate) (B-nBA), polybutadiene-b-poly(n-butyl methacrylate) (B-nBMA) and polybutadiene-b-poly(t-butyl methacrylate) (B-tBMA) did not show such a large choice in selective solvents and spherical micelles were obtained in DMF, DMAc and acetone respectively. Cross-linking of the polybutadiene core of the obtained micelles was performed in solution using two different methods: cold vulcanization and radical reaction upon the decomposition of a photo-initiator under UV radiation. Both methods allow retaining the spherical shape of the micelles leading to narrowly distributed non fusible nanospheres. In the case of B-M nanoparticles, the degree of cross-linking seemed independent of the amount of cross-linker used. Unlikely, B-nBMA and B-nBA nanoparticles exhibited increasing degrees of cross-linking with the amount of photo-initiator introduced. Their degrees of cross-linking were particularly lower than those of B-M nanoparticles. The hydrolysis of the t-BMA corona of the nanoparticles obtained from B-tBMA linear block copolymers self-assembly in selective solvent resulted in water soluble nanoparticles carrying acid functions and thus potentially exhibiting pH-responsive behavior. Various hyperstars consisting of a hyperbranched PB core and (meth)acrylate arms were synthesized by anionic self-condensing vinyl copolymerization (SCVCP) of divinylbenzene and butadiene followed by the anionic polymerization of the linear (meth)acrylate arms. The amount of hyperbranched products resulting from SCVCP could be enhanced by introducing additional DVB to the reaction while polymerizing. The topology of the hyperbranched PB cores was confirmed by viscosity measurements. All Mark-Houwink-Sakurada exponents were significantly below the value for linear PB. The initiation of (meth)acrylate arms was confirmed by NMR spectroscopy. Upon the arm-growth reaction, the branched topology was retained as witnessed by further viscosity measurements. The introduction of cross-linked nanoparticles based on linear block copolymers did not disturb the transparency of PU coatings. Even after curing reaction, the nanoparticles were well-dispersed into the coating. TEM observations confirmed this last result where neither aggregation nor flocculation of the cross-linked nanoparticles was observed. Hyperstar polymers were found to undergo self-assembly upon the curing reaction leading to “onion-like” structured aggregates, in the case of PMMA hyperstars, with sizes as large as 200 nm. Aggregates of the same size order were observed for the other hyperstars but no defined structures were found. For all hyperstar modified coatings, the transparency of the films was altered. In both cases, cross-linked nanoparticles and hyperstar modified coatings, improvements of chip resistance were observed. The improvements were even better with increasing amount of cross-linked nanoparticles but no effect was noticed on the hardness of the coatings. Similar trends were observed for the hyperstar modified coatings.

"Smart" Hydrogels based on Trishydrophilic Triblock Terpolymers (2010)

Stefan Reinicke

The work presented in this thesis focuses on the synthesis of double stimuli-responsive, trishydrophilic triblock terpolymers and their utilization for the construction of “smart” hydrogel systems, responding to a variety of external stimuli. The central focus was put on ABC triblock terpolymers composed of a pH-sensitive A block, a water soluble B block and a thermo-sensitive or multi-responsive C block. This concept was used for the construction of hydrogels responding independently to pH, temperature, and UV light. It was further applied to the formation of polymer/nanoparticle hybrid micelles suitable for the formation of magneto-responsive hydrogels (ferrogels). At first, a new route for the synthesis of block copolymers, containing ethylene oxide and glycidol derivatives, was developed. The crucial aspect of this procedure, based on sequential anionic polymerization, was the utilization of the phosphazene base t-BuP4, enabling the anionic polymerization of epoxide monomers in the presence of lithium counterions. It was shown, that ethoxyethyl glycidyl ether polymerizes easily under the established polymerization conditions without unwanted termination. Hence, we were able to synthesize well-defined block copolymers containing vinyl and epoxide monomers in a one-pot reaction, without performing additional intermediate steps. This new synthetic route was then utilized to synthesize a series of poly(2-vinylpyridine)-block-poly(ethylene oxide)-block-poly(glycidyl methyl ether-co-ethyl glycidyl ether) (P2VP-b-PEO-b-P(GME-co-EGE)) triblock terpolymers suitable for pH and temperature dependent hydrogel formation. The reversible gelation for this particular system relies on two distinct mechanisms. Under conditions, where only one outer block is insoluble, core-shell-corona (CSC) micelles are formed, resulting in gelation via close cubic packing of the micelles. On the other hand, the micelles are also able to crosslink through their corona when both outer blocks are insoluble. As a direct consequence, a temperature triggered gel-sol-gel transition occurred at pH = 7, accompanied by a unique gel strengthening. Solubility and gelation studies were performed by DLS, rheology and SANS. The influence of polymer concentrations and block lengths on the gelation behavior and gel properties was studied. In order to derive information about the exact structure of the cubic lattice formed in the low temperature gel phase (simple cubic or body centered cubic), a 19 wt% aqueous solution of a particular P2VP-b-PEO-b-P(GME-co-EGE) triblock terpolymer at pH = 7 was further investigated using SANS under steady shear. By application of shear stress, the irregularly arranged polydomains of the sample oriented macroscopically along a preferred direction, which led to highly defined, strongly anisotropic 2D scattering patterns. The interpretation of these patterns confirmed the presence of a body centered cubic packing. The gel-sol transition upon temperature increase can be explained by a shrinkage of the shell of the CSC micelles. To increase the versatility of the established hydrogel concept, we further synthesized ABC triblock terpolymers with different responsive polymers as C blocks. This required an alternative synthetic route, combining anionic polymerization and ATRP via “click” chemistry. After optimization of each synthetic step, exemplary poly(2-vinylpyridine)-block-poly(ethylene oxide)-block-poly(oligo(ethylene glycol) methacrylate) (P2VP-b-PEO-b-POEGMA) and poly(2-vinylpyridine)-block-poly(ethylene oxide)-block-poly(dimethyl- aminoethyl methacrylate) (P2VP-b-PEO-b-PDMAEMA) triblock terpolymers were synthesized, respectively, and characterized regarding their solubility and gelation behavior. At pH > 5, P2VP-b-PEO-b-PDMAEMA forms CSC micelles with a P2VP core, and a pH- as well as thermo-sensitive PDMAEMA corona. This particular structure represents a hydrogel, whose temperature dependent response can be easily changed from a gel-sol to a sol-gel transition by increasing the pH from 8 to 9. At pH = 7.5 on the other hand, gel formation is induced by the addition of hexacyanocobaltate(III) ions due to electrostatic interactions between the multivalent cobaltate ions and the charged DMAEMA units, causing a physical crosslinking of the CSC micelles. The gel can subsequently be disintegrated by an exposure to UV-light, based on a UV-catalyzed aquation of the trivalent hexacyanocobaltate(III) ions ions to divalent aquapentacyanocobaltate(III)-ions. In the last part, a new approach was developed to create a novel type of magnetic field-responsive hydrogels (ferrogels), in which the nanoparticles are tightly bound to the polymer matrix. The P2VP block of the previously synthesized P2VP-b-PEO-b-P(GME-co-EGE) triblock terpolymers was quaternized to a low extent and complexed with negatively charged, citrate stabilized maghemite (γ-Fe(III)-oxide) nanoparticles. Using different analytical methods it was shown that well-defined CSC hybrid micelles were obtained with cores formed by a complex of P2VP and 3-4 nanoparticles per core. Concentrated solutions of these micelles are able to form gels depending on temperature, as revealed by rheology measurements. Due to the presence of the maghemite particles, it is possible to induce gelation via remote heating using AC magnetic fields, which was demonstrated by high frequency magnetocalorimetry.

Donor-Acceptor Block Copolymers in Organic Electronics - Spectroscopy, Charge Transport, Morphology and Device Application (2010)

Sven Hüttner

Organic electronic devices have attracted increasing attention over the last decade. The use of organic materials allows the creation of large area, flexible and low-cost lightemitting devices, transistors and photovoltaics. The development of new organic materials contributes to a successful commercialisation. The present work deals with the characterisation of novel donor-acceptor block copolymers and their constituent polymer blocks that are well-suited for organic photovoltaics. Block copolymers phase-separate and self-assemble into nanostructured morphologies due to the covalent linkage of the two blocks. The interplay between intermolecular interactions, mesoscopic crystalline structures and the block copolymer microphase separation determine the material properties and therefore the device characteristics. Thus, these block copolymers offer a unique platform to study the electronic and photophysical properties of confined donor-acceptor systems. This work is concerned with the fundamental characterisation of these properties as well as the application in organic field effect transistors and organic solar cells. The acceptor polymer block poly(perylene bisimide acrylate) (PPerAcr) consists of perylene bisimide (PBI) units that are linked to a polyacrylate backbone. We have investigated the homopolymer PPerAcr, a model block copolymer in conjunction with polystyrene (PS), as well as fully functionalised block copolymers with a donor block either made of poly(vinyl triphenylamine) (PvTPA) or poly(3-hexylthiophene) (P3HT). These polymers offer a set of electronically active materials with several hierarchical structures: The PBI moieties feature intermolecular pi-pi interactions that lead to crystalline side chains of PPerAcr that form a lattice of one-dimensional stacks of PBI. Further nanoscopic structures are induced by the combination of PPerAcr with another amorphous block or another semi-crystalline block such as P3HT due to phase separation. Since PPerAcr is used as an electron transporting material in all subsequent block copolymers, its structural, optical and electronic properties are investigated in detail. The intermolecular interactions of the PBI moieties favour not only charge transport, but also affect the optical properties, due to the electronic coupling of the transition dipole moments. Thus, optical spectroscopy such as absorption and fluorescence spectroscopy give access to information about the intermolecular packing, which is correlated with temperature dependent X-ray diffraction studies. The strong intermolecular packing of the PBI units can be overcome by solvent-vapour exposure. This is especially helpful to induce polymer chain mobility, enabling the completion of block copolymer phase separation for example. This method was studied in detail by means of in-situ spectroscopy and ellipsometry during controlled solvent-vapour exposure. Spincoated films of PvTPA-b-PPerAcr exhibit an incomplete phase separation and can be transformed into an ordered lamellar morphology by solvent-vapour annealing. In addition to PvTPA, we have characterised further poly(triarylamines) with different electron-rich substituents at the TPA units in OFETs. All these polymers are amorphous side-chain polymers. We found the charge carrier mobility to be independent of the molecular weight, though allowing an adjustment of their thermal properties for device fabrication. This is in contrast to P3HT, which is a semi-crystalline, conjugated main chain polymer. X-ray diffraction, steady state and time-resolved spectroscopy, as well as the transistor device characterisation were employed to establish a charge transport - morphology relation for the donor-acceptor block copolymers P3HT-b-PPerAcr containing two crystalline blocks. Controlling the crystallisation preferences of the two blocks leads to a new processing route for OFETs with tunable p-type, ambipolar, or n-type transport through a one-time thermal annealing step. The application of P3HT-b-PPerAcr in organic photovoltaic devices showed also very promising results with high external quantum efficiencies. Subsequently, the photophysics of P3HT-b-PPerAcr by means of absorption and fluorescence spectroscopy as well as time-resolved transient absorption spectroscopy were investigated. All block copolymers exhibited an ultra-fast charge-pair formation and a strongly reduced photoluminescence, suggesting domain sizes of only some nanometres. Although efficient charge separation could be accomplished, a good charge percolation was lacking due to small domain sizes. Furthermore the herein presented results emphasis the fundamental importance of morphology and interfacial properties such as crystallinity. These findings motivate the further use of block copolymers as compatibilising agents for polymer blends to improve their interface and morphology.

Crystalline Morphologies of Poly(butadiene)-b-Poly(ethylene oxide) Block Copolymers in n-Heptane (2009)

Adriana Mirela Mihut

This thesis reports the development of micellar crystalline morphologies in a selective solvent. The phase diagram of solution morphologies as a function of the molecular composition of the semicrystalline poly(butadiene)-b-poly(ethylene oxide)(PB-b-PEO) block copolymers was investigated. The crystalline morphologies discussed here have been generated from selective solvent condition (70°C in n-heptane) via two thermal pathways: (A) by direct immersion into liquid nitrogen, where n-heptane becomes a poor solvent for both blocks at very low temperatures, and (B): by quenching to the crystallization temperature of the PEO, i.e., determined by the length of PEO block. In pathway B, n-heptane is a poor solvent only for the PEO block. At 70°C, the block copolymers self-assembled into micellar structures consisting of a PEO molten core and a soluble PB corona. As crystallization takes place in the PEO core, a fast quenching into liquid nitrogen results in the formation of crystalline micelles retaining the shape present in the molten state at 70°C (pathway A). In the case of pathway B, the competition between the PEO core crystallization and the self-assembly of the micellar units, is the driving force that dictates the morphological development, therefore crystallization breaks out the melt morphology. These studies, demonstrated that the PB-b-PEO block copolymers are a promising system models for developing a general route towards tunable crystalline morphologies. In a symmetric PB-b-PEO block copolymer, crystalline morphologies like spheres and meanders formed upon quenching into liquid nitrogen and at 30°C, respectively. The meander morphology consisting of branched lamellae with a crystalline PEO ribbon-like core and ellipsoidal endings was observed for the first time in solution. Investigations of the crystal development revealed that this structure formed via crystallization-induced aggregation of spherical micelles upon cooling. A systematic study of the effect of crystallization kinetics on the formed morphology upon crystallization-induced aggregation of spherical micelles of a symmetric PB-b-PEO block copolymer was discussed. We demonstrated that the resulting morphology is controlled by two competitive effects, namely, by the nucleation and growth of the PEO micellar core: at lower crystallization temperatures (Tc ≤ 30°C), a high nucleation rate leads to a meander-like morphology formation, whereas at higher crystallization temperatures (Tc > 30°C), a low nucleation rate favors the formation of twisted lamellae. For a highly asymmetric PB-b-PEO block copolymer, crystallization at -30°C induced the formation of crystalline micelles retaining the spherical shape present in the molten state at 70°C. However, a quenching into liquid nitrogen facilitated a transition to rod-like micelles caused by changes of solvent quality for the PB coronar chains. This triggers the onset of an interfacial instability, therefore the spherical micelles preferred to reorganize into a morphology with a smaller interfacial curvature. The low crystallinity of the PEO core imposed a stronger tendency of the rods to aggregate and to thicken into more stable morphologies as needle-like structures, with a preferred growth direction along the long axis. Finally, the micellar morphology diagram of the PB-b-PEO block copolymers has been studied as a function of the crystallization temperature and molecular composition of the blocks via two thermal pathways. Pathway A allowed morphological transitions from spheres to rods, worms or twisted cylinders with the increase of the crystalline content of the PEO core. In Pathway B, the sequence of spheres, cylinders, lamellae, platelets and dendrites structures is observed with the increases of the PEO block length. The aggregation number of the spherical micelles is affected by the weight fraction and crystallinity of the PEO block. Moreover, an increased chain folding was observed at a high PEO composition which reduced the lamellar thickness of the crystals. The competition between the PEO core crystallization and the aggregation of the micellar units leads to coexistence regions of lamellae with platelets and cylinders with platelets. The novelty of this thesis relies on the development of novel crystalline morphologies in a selective solvent, as well as, in the detailed analysis of the major parameters that govern morphological formation in a controlled manner.

Mesoscale Modeling of Phase Behavior in Thin Films of Cylinder-Forming ABA Block Copolymers (2008)

Andriana Horvat

In this thesis modeling results on structure formation in thin films of cylinder-forming block copolymers are presented and discussed. The computational study of the equilibrium phase behavior in thin films is complemented by detailed comparison with a real experimental system. Additionally, the dynamics in such films at various length and time scales (the dynamics of individual defects and the dynamics of surface relief structures) is studied. The strength of the presented thesis is the comparison of thin block copolymer film equilibrium and dynamic behavior in experiments and in computer simulations. This comparison supplies an in-depth understanding of the processes in thin films and near the surfaces in thick films and allows to identify the important control parameters of nanopattern formation. Chapters 4 and 5 report on the phase behavior of thin films of asymmetric block copolymers. In addition to the surface induced alignment of hexagonally ordered cylinders, an adjustment to the planar symmetry of the surface by formation of surface reconstructions is found to dominate the phase behavior in thin films. The large parameter space covered by the simulations allows to distinguish the effects of the two constraints characteristic for thin films: the surface field and the film thickness. The deviations from the bulk cylinder structure, both in the vicinity of surfaces and in thin films are identified as surface reconstructions. The stability regions of different phases are modulated by the film thickness via interference and confinement effects. The results give evidence of a general mechanism that govern the phase behavior in thin films of modulated phases: The interplay between the strength of the surface field and the deformability of the bulk structure determines how the system rearranges in the vicinity of the surface. Chapters 6 and 7 present a systematic study of defects in thin films of cylinder-forming block copolymers. In particular, the peculiarities of both classical and specific topological are considered in detail, and a strong relationship between the defect structures and the chain mobility in block copolymers is observed. In the systems studied, representative defect configurations provide connectivity of the minority phase in the form of dislocations with a closed cylinder end or classical disclinations with incorporated alternative, nonbulk structures with planar symmetry. In solvent-annealed films with enhanced chain mobility, the neck defects (bridges between parallel cylinders) were observed. This type of nonsingular defect has not been identified in block copolymer systems before. It is shown, that topological arguments and 2D defect representation, sufficient for lamellar systems, are not sufficient to determine the stability and mobility of defects in the cylindrical phase. In-situ scanning force microscopy measurements are compared with the simulations based on DDFT. The close match between experimental measurements and simulation results suggests that the lateral defect motion is diffusion-driven. Finally, the morphological evolution is considered with the focus on the motion and interaction of the representative defect configurations. Chapter 7 reveals dynamic simulations and in-situ SFM measurements of defect annihilation. Along with the lateral movement of defects, the annihilation frequently proceeds through local structural transitions. The role of the observed structural evolution is discussed in the context of the equilibrium phase behavior of cylinder-forming thin films, studied in chapters 4-5. Chapter 8 presents a study of terrace formation in thin films of a cylinder-forming block copolymers by a computational DDFT method. The results are compared with in situ SFM measurements of SBS block copolymer thin films. This chapter focuses on the early stage of terrace formation, where 80% of height changes occur. Experimental and simulation results agree that the change of the local height is strongly connected to the changes in the local microstructure. The detailed pathways of the structural transitions, as revealed by simulations, suggest a diffusion of block copolymer chains along the microstructure interfaces and indicate an important role of cylinders with necks as a material-transport-channel between neighboring terraces in thin cylinder-forming films. Both systems (in experiment and in simulations) show excellent quantitative agreement in detail of structural phase transitions and in the dynamics of the step development, suggesting that the underlying transport mechanisms are governed by diffusion.

Novel Semiconductor Block Copolymers for Organic Electronic Devices: Synthesis, Properties and Applications (2009)

Michael Sommer

Diese Arbeit beschreibt die Synthese und Charakterisierung von neuartigen, maßgeschneiderten Donor-Akzeptor (D-A) Blockcopolymeren mit elektronisch funktionellen Blöcken, sowie deren Anwendung in organischen Feldeffekttransistoren und organischen Solarzellen. Die hergestellten D-A Blockcopolymere können in zwei Klassen unterteilt werden: Blockcopolymere mit einem amorphen und einem kristallinen Block und Blockcopolymere mit zwei kristallinen Blöcken. Die Synthese dieser neuen Materialien verlangt die geschickte Kombination von klassischer organischer Chemie mit einer oder zwei Polymerisationsmethoden. Die Besonderheit solcher aufwendigen Blockcopolymere liegt in ihrer Fähigkeit zur Mikrophasenseparation. Die dadurch entstehenden Domänengrößen liegen im Bereich der Exzitonendiffusionslänge, wodurch D-A Blockcopolymere als äußerst vielversprechend für Ladungstrennung und Ladungstransport gelten. Die Selbstaggregation der D-A Blockcopolymere wird vom Zusammenspiel verschiedener Kräfte geleitet: Kristallisation eines oder zweier Blöcke und Mikrophasenseparation. Solche Materialien mit definierten Moleküleigenschaften sind bisher sehr wenig erforscht und ermöglichen es, die D-A Grenzfläche in dünnen Filmen präzise einzustellen. Um definierte Blockcopolymerarchitekturen herzustellen, wurden zwei verschiedene Polymerisationsmethoden mit lebendem Charakter verwendet, kombiniert und angepasst: Nitroxid-vermittelte radikalische Polymerisation (NMRP) und Grignard Metathese Polymerisation (GRIM). Die Grignard Metathese Polymerisation wurde erfolgreich optimiert und verwendet, um mehrere Poly(3-hexylthiophen)P3HT-Blöcke mit kontrolliertem Molekulargewicht und niedriger Polydispersität herzustellen. Weiterhin wurde eine einfache und zielgerichtete Eintopfreaktion entwickelt, um P3HT-Makroinitiatoren für die NMRP herzustellen. Ausgehend von diesen Makroinitiatoren wurden mehrere definierte Blockcopolymere mit P3HT und Perylen Bisimidacrylat PerAcr mit unterschiedlicher Komposition und unterschiedlichem Molekulargewicht synthetisiert. Die Besonderheit von P3HT-b-PPerAcr liegt in der kristallin-kristallinen Blockcopolymerarchitektur, wobei das erste Segment hauptkettenkristallin und das zweite Segment seitenkettenkristallin ist. Der kristallin-kristalline Charakter wurde mittels differentieller Wärmeflußkalorimetrie und Röntgenstreuung bestätigt, wobei eine Koexistenz von lamellaren P3HT- und eindimensionalen PPerAcr Stapeln festgestellt wurde. Die Koexistenz dieser Aggregate ist maßgeblich von der Komposition, dem Molekulargewicht, und der Vorbehandlung von P3HT-b-PPerAcr abhängig. Während thermisch vorbehandelte Proben eine verstärkte Ausbildung von kristallinen PPerAcr Domänen zeigen, fördert die Lösungsmitteldampfbehandlung die Aggregation von P3HT. Dieser Effekt wird übereinstimmend bei der Untersuchung der optischen, thermischen, morphologischen und elektrischen Eigenschaften gefunden. Die Herstellung von organischen Solarzellen mit P3HT-b-PPerAcr als aktiver Schicht ergab einen Rekordwert der externen Quantenausbeute von 31 %, was für die beiden Komponenten P3HT und Perylenbisimid den höchsten gemessenen Wert darstellt.

New Approaches to the Synthesis of Porous and/or High Surface Area Transition Metal Oxides (2009)

Ram Sai Yelamanchili

We have explored the applicability of hypothesized approaches to the synthesis of porous and/or high surface area transition metal oxides. In addition, applicability and advantage of charged templates where strong Coulomb interactions favour the supramolecular arrangements/assembly were studied. The problems related with the dynamics of polymeric nanostructures for the synthesis of predesigned mesostructures could be avoided by crosslinking micelles, strictly speaking non-continuous phase in the bulk structure. Thereby, we presented a new approach for the grafting of Keggin POMs around the core-crosslinked PB-P2VP worm-like polymer templates (A 1 and 2). The produced POM-1 exhibits high dispersion, improved surface area and is thus expected to be useful in catalytic, electrochemical and biotechnology related applications. The general applicability of the method to other Keggin POMs and spherical polymer nanostructures were studied. Developed Keggin POMs-1 to 6 showed high dispersion of Keggin POM and surface areas. To the best of our knowledge, our approaches lead to Keggin POM nanocomposites with the highest surface areas reported todate. As-synthesized Keggin POM nanocomposites are amorphous. We have studied the removal of polymer template and crystallization of hybrid to corresponding metal oxides through step-wise calcinations under argon followed by air. We have presented another approach to the synthesis of high surface area and mesoporous keggin POM framework materials using amphiphilic PI-PDMAEMA block copolymers (A 3). The calcined mesoporous materials exhibit Keggin POM hexagonal pore structure with high keggin POM dispersion, improved surface area. These developed materials are expected to be useful in catalytic applications. A fundamental principle involved in this method is that an attractive interaction between the organic block copolymer and the keggin POM precursors is obtained via Coulombic interactions through in situ quaternization (protonation) of PDMAEMA part, which also ensure the formation of a homogeneous hybrid material without any macrophase separation. Further, step-wise calcinations under argon and air lead to evolution of mesoporous keggin POM material. To the best of our knowledge, this is the first hexagonally ordered mesoporous Keggin POM framework material. We have presented a low-temperature, non-hydrothermal synthesis route to rutile nanocrystals. Both rutile and anatase nanocrystals exhibit positive surface charges. In contrary to the above approaches where polymer templates are cationic and inorganic precursors are anionic, in this case, inorganic nanocrystals are cationic and polymer templates are anionic. In this approach, we have demonstrated that crystalline TiO2 nanocomposites with well-defined crystalline form could be directly synthesized at temperatures as low as 40 oC by mesostructuring the positively charged crystalline titania colloids over anionic spherical polyelectrolyte brush particles under aqueous conditions. Stepwise calcinations first under argon followed with a second calcination in air lead to the complete removal of polymer template without collapse and hollow porous spheres with crystalline framework are obtained. Porosity and surface areas increased dramatically after stepwise calcinations. Moreover, the porous rutile nanomaterials are photocatalytically active. We proved that our hypothesis to the synthesis of crystalline TiO2 nanocomposites with well-defined crystalline form and morphologie is feasible.

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