[PDF] Kinetic Assembly Of Block Copolymers In Solution Helical Cylindrical Micelles And Patchy Nanoparticles eBook

Author : Sheng Zhong
Publisher :
Page : pages
File Size : 28,33 MB
Release : 2010
Category : Block copolymers
ISBN : 9781124241562

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There is always an interest to understand how molecules behave under different conditions. One application of this knowledge is to self-assemble molecules into increasingly complex structures in a simple fashion. Self-assembly of amphiphilic block copolymer in solution has produced a large variety of nanostructures through the manipulation in polymer chemistry, assembly environment, and additives. Moreover, some reports suggest the formation of many polymeric assemblies is driven by kinetic process. The goal of this dissertation is to study the influence of kinetics on the assembly of block copolymer. The study shows kinetic control can be a very effective way to make novel polymeric nanostructures. Two examples discussed here are helical cylindrical micelles and patchy nanoparticles. Helical cylindrical micelles are made from the co-assembly of amphiphilic triblock copolymer poly(acrylic acid)- block -poly(methyl acrylate)- block -polystyrene and organoamine molecules in a mixture of tetrahydrofuran (THF) and water (H 2 O). This system has already shown promise of achieving many assembled structures. The unique aspects about this system are the use of amine molecules to complex with acid groups and the existence of cosolvent system. Application of amine molecules offers a convenient control over assembled morphology and the introduction of PMA-PS selective solvent, THF, promotes the mobility of the polymer chains. In this study, multivalent organoamine molecules, such as diethylenetriamine and triethylenetetramine, are used to interact with block copolymer in THF/water mixture. As expected, the assembled morphologies are dependent on the polymer architecture, selection and quantity of the organoamine molecules, and solution composition. Under the right conditions, unprecedented, multimicrometer-long, supramolecular helical cylindrical micelles are formed. Both single-stranded and double-stranded helices are found in the same system. These helical structures share uniform structural parameters, including the width of the micelles, width of the helix, and the pitch distance. There is no preference to the handedness, and both handednesses are observed, which is understandable since there are no chiral molecules or specific binding effects applied during the assembly. The helical structure is a product of kinetic process. Cryogenic transmission electron microscopy has been employed to monitor the morphological transformation. The study indicates there are two complicated but reproducible kinetic pathways to form the helices. One pathway involves the stacks of bended cylinders at early stages and the subsequent interconnection of these bended cylinders. Spherical micelles bud off of the interconnected nanostructure as the final step towards a defect-free helix. Another kinetic pathway shows very short helices are formed at first and aligned via head-to-tail style in the solution, and the subsequent sequential addition of these short helices results in prolonged mature helices. By using a ninhydrin-staining technique, amine molecules within the micellar corona are visualized and confirmed to preferentially locate in the inner side of the helical turns. The aggregation of amine molecules provides a strong attraction force due to electrostatic association between oppositely charged amine and acid groups and accumulation of hydrogen bonding among amine molecules to coil the cylindrical micelles into helical twisting features which are stabilized by the repulsion forces due to the chain packing frustration within the hydrophobic core, steric hindrance of amine molecules as well as the Coulomb repulsion of the excess charged amine groups. The formation mechanism of the helix offers the feasibility to manipulate the helical pitch distance and formation kinetics. The helical pitch distance can be enlarged or shrunk by varying the type and amount of amine molecules used in assembly, introducing inorganic salts, and changing pH. Luckily, the helical structure can be preserved permanently by inducing the amide reaction between amine and carboxylic acid groups. The kinetics of the helix is also subject to many factors, including used amine molecules, inorganic salts and preparation procedure. The aging time for the helix can be either reduced or prolonged. Furthermore, even though the helical formation is pathway-dependent, helical formation can still be triggered from extended cylindrical micelles or stacks of disklike micelles as long as a right condition is applied. Another strategy for kinetic assembly of block copolymer is presented as well. A novel patchy nanoparticle has been produced following this strategy. The patches are formed on the surface of polymeric colloids due to the phase separation of two chemically unlike segments. Certain level of mobility of the polymer chains is required for the blocks to segregate into patches. More importantly, the number and distribution geometry of the patches are related to the particle size. Future efforts are needed to control the particle size in order to manufacture uniform nanoparticles with desired patch patterns for the applications in nanotechnology, drug delivery and nanodevices.

Author : Massimo Lazzari
Publisher : John Wiley & Sons
Page : 447 pages
File Size : 20,31 MB
Release : 2007-06-27
Category : Technology & Engineering
ISBN : 3527610561

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This first book to take a detailed look at one of the key focal points where nanotechnology and polymers meet provides both an introductory view for beginners as well as in-depth knowledge for specialists in the various research areas involved. It investigates all types of application for block copolymers: as tools for fabricating other nanomaterials, as structural components in hybrid materials and nanocomposites, and as functional materials. The multidisciplinary approach covers all stages from chemical synthesis and characterization, presenting applications from physics and chemistry to biology and medicine, such as micro- and nanolithography, membranes, optical labeling, drug delivery, as well as sensory and analytical uses.

Author : Ian W. Hamley
Publisher : John Wiley & Sons
Page : 300 pages
File Size : 21,52 MB
Release : 2005-12-13
Category : Technology & Engineering
ISBN : 0470016973

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This unique text discusses the solution self-assembly of block copolymers and covers all aspects from basic physical chemistry to applications in soft nanotechnology. Recent advances have enabled the preparation of new materials with novel self-assembling structures, functionality and responsiveness and there have also been concomitant advances in theory and modelling. The present text covers the principles of self-assembly in both dilute and concentrated solution, for example micellization and mesophase formation, etc., in chapters 2 and 3 respectively. Chapter 4 covers polyelectrolyte block copolymers - these materials are attracting significant attention from researchers and a solid basis for understanding their physical chemistry is emerging, and this is discussed. The next chapter discusses adsorption of block copolymers from solution at liquid and solid interfaces. The concluding chapter presents a discussion of selected applications, focussing on several important new concepts. The book is aimed at researchers in polymer science as well as industrial scientists involved in the polymer and coatings industries. It will also be of interest to scientists working in soft matter self-assembly and self-organizing polymers.

Author : P. Alexandridis
Publisher : Elsevier
Page : 449 pages
File Size : 26,39 MB
Release : 2000-10-18
Category : Science
ISBN : 0080527108

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It is the belief of the editors of this book that the recognition of block copolymers as being amphiphilic molecules and sharing common features with other well-studied amphiphiles will prove beneficial to both the surfactant and the polymer communities. An aim of this book is to bridge the two communities and cross-fertilise the different fields. To this end, leading researchers in the field of amphiphilic block copolymer self-assembly, some having a background in surfactant chemistry, and others with polymer physics roots, have agreed to join forces and contribute to this book.The book consists of four entities. The first part discusses theoretical considerations behind the block copolymer self-assembly in solution and in the melt. The second part provides case studies of self-assembly in different classes of block copolymers (e.g., polyethers, polyelectrolytes) and in different environments (e.g., in water, in non-aqueous solvents, or in the absence of solvents). The third part presents experimental tools, ranging from static (e.g., small angle neutron scattering) to dynamic (e.g., rheology), which can prove valuable in the characterization of block copolymer self-assemblies. The fourth part offers a sampling of current applications of block copolymers in, e.g., formulations, pharmaceutics, and separations, applications which are based on the unique self-assembly properties of block copolymers.

Author :
Publisher :
Page : pages
File Size : 39,2 MB
Release : 2009
Category : Block copolymers
ISBN : 9780549924067

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Self-assembling amphiphilic block copolymers have been studied extensively due to their ability to form a wide range of morphologies including spheres, cylinders, and vesicles. Changing the molecular composition of the block copolymer, the relative block lengths, and the solution conditions can alter the assembly behavior. The main goal of this dissertation is to investigate the self-assembly of two different amphiphilic block copolymer systems in an effort to controllably make different assembled structures. Amphiphilic, triblock copolymers of poly(acrylic acid)- b -poly(methyl acrylate)- b -polystyrene (PAA-PMA-PS) in tetrahydrofuran (THF)/ water solvent mixtures were studied. The solution conditions and the relative block lengths were varied, and complexation with an amine counterion was used to influence the self-assembly of these materials. A variety of structures were observed including phase-separated nanoparticles, bulk-like lamellar phase separation, spherical, cylindrical, and disk-like micelles, as well as toroidal assemblies. The specific structure formed was dependent on the composition of the triblock copolymer, the amount and valency of the counterion present, and the THF to water volume ratio. The structure of polymer nanoparticles and networks formed in low water content systems was examined. The size of the nanoparticles and whether separated nanoparticles vs. an interconnected network was formed was controlled via solvent composition. Importantly, both the nanoparticles and network phases contained their own inherent nanostructure due to local phase separation of the block copolymers. This phase behavior within the nanoparticles could be tuned, i.e. porous or lamellar internal structure, by changing the valency of the amine counterion. Cryo-transmission electron microscopy (TEM), traditional TEM, and neutron scattering were used to examine these samples. In addition to these triblock copolymers, amphiphilic diblock copolypeptides of hydrophobic leucine (L) and hydrophilic lysine (K) with poly(ethylene glycol) side groups were investigated. The effect of the copolypeptide design on the resulting morphology was studied by examining diblock compositions with different block lengths and secondary structures. It was determined that the secondary structure of these peptides plays a significant role in influencing the assembly of these materials.

Author : Roel Gronheid
Publisher : Woodhead Publishing
Page : 328 pages
File Size : 36,10 MB
Release : 2015-07-17
Category : Technology & Engineering
ISBN : 0081002610

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The directed self-assembly (DSA) method of patterning for microelectronics uses polymer phase-separation to generate features of less than 20nm, with the positions of self-assembling materials externally guided into the desired pattern. Directed self-assembly of Block Co-polymers for Nano-manufacturing reviews the design, production, applications and future developments needed to facilitate the widescale adoption of this promising technology. Beginning with a solid overview of the physics and chemistry of block copolymer (BCP) materials, Part 1 covers the synthesis of new materials and new processing methods for DSA. Part 2 then goes on to outline the key modelling and characterization principles of DSA, reviewing templates and patterning using topographical and chemically modified surfaces, line edge roughness and dimensional control, x-ray scattering for characterization, and nanoscale driven assembly. Finally, Part 3 discusses application areas and related issues for DSA in nano-manufacturing, including for basic logic circuit design, the inverse DSA problem, design decomposition and the modelling and analysis of large scale, template self-assembly manufacturing techniques. Authoritative outlining of theoretical principles and modeling techniques to give a thorough introdution to the topic Discusses a broad range of practical applications for directed self-assembly in nano-manufacturing Highlights the importance of this technology to both the present and future of nano-manufacturing by exploring its potential use in a range of fields

Author : Gity Mir Mohamad Sadeghi
Publisher : Elsevier Inc. Chapters
Page : 121 pages
File Size : 26,40 MB
Release : 2013-11-28
Category : Technology & Engineering
ISBN : 0128090847

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Block copolymers (BCPs) consist of two or more chemically different polymers connected covalently, and are polymer alloys. Due to their thermodynamic incompatibility and chain connectivity, the phase separation between two (or more) blocks occurs only in a tens of nanometers range. Nanostructures are based on block copolymer self-assembly. They are functional nanomaterials less than 100nm in size and have received extensive scientific and technological attention due to their potential applications in electronic, biomedical, and optical materials. This chapter examines a variety of different synthetic strategies for preparation of linear diblock copolymers by anionic polymerization. Triblocks can be synthesized according to an appropriate synthetic pathway, depending on the monomers used and their sequence in the triblock chain. Nonlinear block copolymers including star block copolymers, graft copolymers, miktoarm star copolymers, cyclic block copolymers, and other complex architectures are explained. Microphase separation drives BCPs to self-assemble, resulting in ordered nanostructures, including spheres, cylinders, gyroids, and lamellae, depending on the composition of the BCP. In nanotechnology, self-assembly (SA) underlies various types of molecular structures built from nanoparticles, nanotubes, or nanorods. Supramolecular structures generated from amphiphilic block copolymers are characterized by a slow rate of intermicellar chain exchange which makes them interesting for a variety of applications. Basic principles of self-assembly and micellization of block copolymers in dilute solution, methods for stabilization of the macromolecular aggregates, are discussed. Stabilized nanoparticles, the so-called “smart materials,” which show responses to environmental changes (pH, temperature, ionic strength, etc.), are presented with a focus on their applications.

Author : Holger Schmalz
Publisher :
Page : 200 pages
File Size : 26,3 MB
Release : 2022-03-14
Category :
ISBN : 9783036533261

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Block copolymers with crystallizable blocks have moved into the focus of current research, owing to their unique self-assembly behaviour and properties. New synthetic concepts give, for example, even access to tetrablock copolymers with four crystalline blocks, bio-based thermoplastic elastomers (e.g., based on ABA triblock copolymers with poly(L-lactide) (PLLA) hard segments), and allow new, exciting insights into the interplay of microphase separation and crystallization in controlling self-assembly in bulk (confined vs. break-out crystalliza-tion). Concerning self-assembly in solution, crystallization-driven self-assembly (CDSA) paved the way to a myriad of crystalline-core micellar structures and hierarchical super-structures that were not accessible before via self-assembly of fully amorphous block copolymers. This allows for the production of cylindrical micelles with defined lengths, length distribution, and corona chemistries (block type or patchy corona), as well as branched micelles and fascinating micellar superstructures (e.g., 2D lenticular platelets, scarf-shaped micelles, multidimensional micellar assemblies, and cross and "windmill"-like supermicelles). This Special Issue brings together new developments in the synthesis and self-assembly of block copolymers with crystallizable blocks and also addresses emerging applications for these exciting materials. It includes two reviews on CDSA and eight contributions spanning from membranes for gas separation to self-assembly in bulk and solution.