Small-angle X-ray scattering from styrene-butadiene-styrene block copolymers

Abstract

A new type of time-dependent and strain-history-dependent viscoelasticity was discovered in semidilute polymer solutions. Dynamic moduli G′ and G″ of 20% and 10% nitrile butadiene rubber (NBR) solutions were recorded as a function of time while oscillatory shear deformations were maintained. The moduli decrease with time was observed only at lower frequencies. The time dependence of G′ was more pronounced than that of G″. At a higher temperature, the time dependence was extended toward higher frequencies also, and the time dependence became stronger. Lowering the concentration of solution gave a similar effect as increasing temperature. After the cessation of oscillations, a slow recovery was observed. The recovery was somewhat faster at the higher temperature. The time-dependent moduli and their recovery were explained by the change and recovery of structures associated with long branches and gels in the NBR. The structure change occurred at higher frequencies also, but it was not observed during the application of oscillation. Only in subsequent measurements at lower frequencies could the structure change be detected. Thus, the change may be regarded as strain history dependent. The mechanism of the structural change was explained with either the entanglement or osmotic pressure models, depending on concentration.     

Self-assembly of rod-coil block copolymers from weakly to moderately segregated regimes

We report on the self-assembly behaviour of two homologue series of rod-coil block copolymers in which, the rod, a π -conjugated polymer, is maintained fixed in size and chemical structure, while the coil is allowed to vary both in molecular weight and chemical nature. This allows maintaining constant the liquid crystalline interactions, expressed by Maier-Saupe interactions, ω , while varying the tendency towards microphase separation, expressed by the product between the Flory-Huggins parameter and the total polymerization degree, χN . Therefore, the systems presented here allow testing directly some of the theoretical predictions for the self-assembly of rod-coil block copolymers in a weakly segregated regime. The two rod-coil block copolymer systems investigated were poly(DEH-p-phenylenevinylene-b-styrene), whose self-assembly takes place in the very weakly segregated regime, and poly(DEH-p-phenylenevinylene-b-4vinylpyridine), for which the self-assembly behaviour occurs under increased tendency towards microphase separation, hereby referred to as moderately segregated regime. Experimental results for both systems are compared with predictions based on Landau expansion theories.     

Confinement-induced novel morphologies of block copolymers

Self-assembly of block copolymers confined in cylindrical nanopores is studied systematically using a simulated annealing technique. For diblock copolymers which form two-dimensional hexagonally packed cylinders with period L0 in the bulk, novel structures such as helices and stacked toroids spontaneously form inside the cylindrical pores. These confinement-induced morphologies have no counterpart in the bulk system and they depend on the pore diameter (D) and the surface-polymer interactions, reflecting the importance of structural frustration and interfacial interactions. On tightening the degree of confinement, transitions from helices to toroids to spheres are observed. Mechanisms of the morphological transitions can be understood based on the degree of structural frustration parametrized by the ratio D/L0.     

Monolayers of graft and block copolymers

Surface pressure-area isotherms for monolayers from graft copolymers with one branch (or four) and diblock copolymers were determined at air/aqueous medium interfaces. The dependence of surface pressure on area for poly(vinyl acetate) (PVAc)-polystyrene(PS) graft and block copolymers was identical to that of pure PVAc at the large areas, while a sharp increase in pressure appeared with further compression. The surface pressure of PVAc-PS graft copolymer at the air/0. 2 N NaOH interface decreased with time, but the critical area at which the surface pressure increased rapidly remained constant, regardless or hydrolysis time. When a poly(vinyl alcohol) (PVA)-PS graft or block copolymer was spread over water, the surface pressure originating from the PVA chain was too small to be observed, and merely that of the PS sequence appeared. It was concluded that the PS sequence was always present in the form of a tightly coiled sphere at the interfaces, whereas the PVAc sequence was spread as a monomolecular film on water but diffused into the alkaline substrate as a result of the hydrolysis to PVA. Thus the PVA-PS graft and block copolymers spread on water seem to be so oriented that the PVA chain “dissolved” in water is supported at the interface by the compact, monomolecular particle of PS on the surface.     

Gas transport in segmented block copolymers

The diffusive transport of several simple gases in four thermoplastic elastomers was measured. Certain anomalies were observed with the larger-sized penetrants, namely Ar and N2. It appears that these gaseous penetrants can distinguish between the rigid and flexible regions of certain block copolymers, the effect being more pronounced for the gas with the larger molecular diameter. A model is proposed and discussed which is qualitatively consistent with the observed behavior.     

Mechanism for hierarchical self-assembly of nanoparticles on scaffolds derived from block copolymers

Lithographically patterned substrates can direct the self-assembly of block copolymer films into aligned structures that, in turn, template the self-organization of colloidal nanoparticles. Deposition on pristine diblock copolymer films does not lead to reproducible selective decoration, but films modified to have nanoscale corrugation act as scaffolds for highly selective nanoparticle adsorption. The mechanism for this selectivity relies on the lateral forces inherent to spin casting to remove all of the nanoparticle suspension not confined within the nanoscopic trenches. This technique does not rely on interactions between the surfactant capping molecules and the polymer and is therefore general to a wide class of nanoparticle materials. Prospects to obtain long-range ordering and associated potential applications are discussed.     

Discovering new ordered phases of block copolymers

We propose a new and general method for discovering novel ordered phases of block copolymer melts. The method involves minimizing a free energy functional in an arbitrary unit cell with respect to the composition profile and the dimensions of the unit cell, without any prior assumption of the microphase symmetry. Varying the initial conditions allows to search for different stable and metastable structures. Application of this method to ABC star and linear triblock copolymers using an approximate free energy reveals new morphologies not yet observed in experiment.     

Composition and molecular weight distribution of block copolymers

The composition distribution (CS) of diblock copolymers of styrene and methyl methacrylate, prepared anionically via a sequential addition procedure, has been investigated by two methods, one based on the theory of light scattering from copolymer solutions and the other on the principle of adsorption chromatography. Calculations were carried out to show that if the structure of the sample block copolymer is described by random coupling statistics, information of the molecular weight distribution (MWD) for either one of the block chains can be drawn from light scattering data obtained with one single solvent in which the solute is invisible. In practice, bromobenzene was used as a solvent appropriate for this purpose. Since the MWD for the precursor polystyrene is known, the MWD for the poly(methyl methacrylate) block was determined by this method. By using these data and assuming the Schulz distribution for MWD, the CD curve was calculated. Fractionation of the block copolymer sample by composition was made on a semipreparative scale (300 mg) by employing a glass cylinder packed with activated silica gel. The elution was carried out with a binary mixture of ethyl acetate and benzene. The fractionation was achieved without interference of molecular weight. Nine fractions having different styrene contents were recovered and analyzed to construct the CD curve. The CD curves obtained by the chromatographic method were in good agreement with those drawn from the light scattering data.     

Thermodynamics of ion-containing polymer blends and block copolymers

We develop a theory for the thermodynamics of ion-containing polymer blends and diblock copolymers, taking polyethylene oxide (PEO), polystyrene and lithium salts as an example. We account for the tight binding of Li^{+} ions to the PEO, the preferential solvation energy of anions in the PEO domain, the translational entropy of anions, and the ion-pair equilibrium between EO-complexed Li^{+} and anion. Our theory is able to predict many features observed in experiments, particularly the systematic dependence in the effective χ parameter on the size of the anions. Furthermore, comparison with the observed linear dependence in the effective χ on salt concentration yields an upper limit for the binding constant of the ion pair.     

Studying the structure of siloxane-urethane-ethylene oxide block copolymers

The structure of siloxane-urethane-ethylene oxide block copolymers is studied by means of atom force microscopy (AFM) and scanning electron microscopy (SEM). The degree of copolymer crystallinity is determined by X-ray diffraction. A correlation between the obtained results is established.     

Statistical thermodynamics of block copolymers: Network statistics

The swelling behavior of a lamellar domain system of an ABA block copolymer is treated, with account taken of the relative population of the B chains as “loops” and “bridges.” The swelling behavior is not a sensitive function of these configurations, since both types in condensed systems are elastically effective, in contrast to the behavior of isolated chains.     

Discovering ordered phases of block copolymers: new results from a generic Fourier-space approach

A generic Fourier-space approach to solve the self-consistent field theory of block copolymers is developed. This approach is based on the fact that, for any computational box with periodic boundary conditions, all spatially varying functions are spanned by the Fourier series determined by the size and shape of the box. The method reproduces all known diblock copolymer phases. The application of this method to a model "frustrated" triblock copolymer leads to a phase diagram with a number of new phases. Furthermore, the capability of the method to reproduce experimentally observed structures is demonstrated using the knitting pattern of triblock copolymers.     

Stabilizing co-continuous polymer blend morphologies with ABC block copolymers

We suggest that ABC triblock copolymers provide a convenient and effective route to emulsifying blends of A and C homopolymers into co-continuous morphologies over a wide range of compositions. Direct transitions between disordered tricontinuous phases (“ABC microemulsions”) and spatially-periodic tricontinuous phases (e.g. gyroid or double-diamond cubic phases) should be possible in appropriately formulated alloys. We envision a broad range of potential applications to thermoplastic and thermoset polymeric materials. Received: 4 June 1997 / Revised: 17 September 1997 / Accepted: 13 October 1997     

Large scale simulation of block copolymers with cell dynamics

Cell dynamics simulation (CDS) is a fast method to simulate kinetic processes in phase separating systems of large sizes. We review this method applied to block copolymer systems and illustrate it on a set of physical phenomena occurring in these systems. Achievements of CDS demonstrate, that the method can describe such complex phenomena rather well and therefore, is a complementary method to other more elaborate but slow techniques to which it can serve as a precursor.     

Characterization of poly(dimethylsiloxane)-polycarbonate block copolymers

Shear modulus-temperature curves and swelling behavior of poly(dimethylsiloxane)-bisphenol-A polycarbonate block copolymers were studied. Two glass transitions corresponding to the silicone and polycarbonate phases are found. A correlation of the shear modulus between the two glass transitions and the swelling ratio of the rubbery phase is suggested.     

Phase behavior in thin films of cylinder-forming block copolymers

We have experimentally determined a phase diagram for cylinder-forming polystyrene-block-polybutadien-block-polystyrene triblock copolymer in thin films. The phase behavior can be modeled in great detail by dynamic density functional theory. Deviations from the bulk structure, such as wetting layer, perforated lamella, and lamella, are identified as surface reconstructions. Their stability regions are determined by an interplay between surface fields and confinement effects.