A theoretical and simulation study of the self-assembly of a binary blend of diblock copolymers

Padmanabhan, Poornima; Martínez-Veracoechea, Francisco J.; Araque, Juan C.; Escobedo, Fernando A.

doi:10.1063/1.4729159

Cited by 19 publications

(20 citation statements)

References 32 publications

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“…Whereas cylinders are almost as well studied as lamellas, the S microstructure in copolymers is rather common only in experimental systems, where it can be obtained either by orderdisorder transition (ODT) 56 or order-order transition (OOT). 57 Its identification by SCFT, 13 in Monte Carlo 19,20 and even DPD 25,41 simulations is usually difficult, if not impossible because of the long equilibration time. Figure 5 reports on the least ordered structures with illdefined peaks on the S(q) dependence.…”

Section: Structure Analysismentioning

confidence: 99%

“…In the field of block copolymers, this general tendency stimulated two lines of research. First of them implies developing hybrid techniques [10][11][12][13] that involve the concept of a self-consistent field into the calculation of interactions in the ensemble of particles. In that way, the evaluation of interchain interactions becomes a considerably less time-consuming procedure.…”

Section: Introductionmentioning

confidence: 99%

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Phase diagrams of block copolymer melts by dissipative particle dynamics simulations

Гаврилов

Kudryavtsev

Chertovich

2013

The Journal of Chemical Physics

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Phase diagrams for monodisperse and polydisperse diblock copolymer melts and a random multiblock copolymer melt are constructed using dissipative particle dynamics simulations. A thorough visual analysis and calculation of the static structure factor in several hundreds of points at each of the diagrams prove the ability of mesoscopic molecular dynamics to predict the phase behavior of polymer systems as effectively as the self-consistent field-theory and Monte Carlo simulations do. It is demonstrated that the order-disorder transition (ODT) curve for monodisperse diblocks can be precisely located by a spike in the dependence of the mean square pressure fluctuation on χN, where χ is the Flory-Huggins parameter and N is the chain length. For two other copolymer types, the continuous ODTs are observed. Large polydispersity of both blocks obeying the Flory distribution in length does not shift the ODT curve but considerably narrows the domains of the cylindrical and lamellar phases partially replacing them with the wormlike micelle and perforated lamellar phases, respectively. Instead of the pure 3d-bicontinuous phase in monodisperse diblocks, which could be identified as the gyroid, a coexistence of the 3d phase and cylindrical micelles is detected in polydisperse diblocks. The lamellar domain spacing D in monodisperse diblocks follows the strong-segregation theory prediction, D∕N(1∕2) ~ (χN)(1∕6), whereas in polydisperse diblocks it is almost independent of χN at χN < 100. Completely random multiblock copolymers cannot form ordered microstructures other than lamellas at any composition.

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Section: Structure Analysismentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Phase diagrams of block copolymer melts by dissipative particle dynamics simulations

Гаврилов

Kudryavtsev

Chertovich

2013

The Journal of Chemical Physics

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“…Investigation of the phase morphology and evolution kinetics of the materials was performed using a mesoscale molecular dynamics method. Dissipative particle dynamics (DPD) is a simulation technique that typically maps multiple chain “mers” into highly coarse-grained “particles” to study the mesophase formation of block polymers with various molecular architectures. − Accordingly, DPD can model physical phenomena occurring at the larger time and spatial scales than typical molecular dynamics. DPD incorporates the Flory–Huggins χ parameter by adding a scaling factor a ij to a repulsive conservative potential; that is, a ij ≈ a ii + 3.27χ ij , when a ii = 25 for a particle number density (ρ) of 3.…”

Section: Results and Discussionmentioning

confidence: 99%

Topological Frustration as a New Parameter to Tune Morphology Revealed through Exploring the Continuum between A-B-C 3-Arm Star and Linear Triblock Polymers

et al. 2021

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Block polymers assemble into a variety of phase-separated morphologies based on volume fraction (φ) and interactions (χ) of the respective blocks. The arrangement of three different polymer blocks could either be a 3-arm star, with each block having one terminus attached to a common junction point or a linear A-B-C architecture. A versatile strategy is reported to synthesize a series of well-defined graft polymers that lie along the unexplored continuum between a 3-arm star and an A-B-C linear triblock polymer architecture. Using the technique of single-molecule insertion, precise control over the position of graft arm C along the B chain was achieved. A series of discrete graft polymers (PMMA-b-PS-g-PEO) with fixed φ and prescribed ω values that lie on the continuum between a 3-arm star (ω = 0) and linear triblock polymer (ω = 1) were synthesized. Morphological studies using small-angle X-ray scattering and conventional and energy-filtered transmission electron microscopy reveal the transition between lamellae, perforated lamellae, and cylindrical morphologies with systematic variation in the ω values, a trend attributed to the topological frustration and the associated χ values between the three blocks. Molecular dynamic simulations of coarse-grained models were found to predict phase diagrams that are consistent with the experimentally observed morphologies. Our results suggest that changes in ω lead to topological frustration which is an important additional new design parameter that can be used to tune the morphology of multiblock polymers in addition to φ and χ.

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“…The binary blends of diblocks, AB/AB, have been intensively examined both experimentally and theoretically since the 1980s, 3−39 not only for the purpose of the morphology control 3,7,10−12,14,15,18,21,22,25,33 but also for many other aspects, such as elucidation of the cosurfactant effects (mixtures of small amounts of short diblocks in the long diblocks), 3−5,8,9,13,16,17,26,28−31,33,35,36,38 anomalous temperature behavior of the domain spacing, 11,19,24,27,29,31,35,39 elucidation of the effects of cast solvent on the morphology in thin films, 32,34 and examination of the grain boundary structure between the macroscopically phase-separated grains of thick and thin lamellae. 6 For these many purposes, a variety of AB/AB binary blends have been examined, such as [long symmetric AB]/[short symmetric AB] blends, 3−6,8,9,13,16,17,26,29,36 [long asymmetric AB]/[short symmetric AB] blends, 14,24,28,30,31,35,38 [asymmetric AB]/[symmetric AB] blends (with similar molecular weights), 15,25 and antisymmetric AB/AB blends (with similar molecular weights). 7,10−12,18−23,27,32−34,37,39 Furthermore, binary blends of AB/ABA 3,40−44 and ABA/ABA 45−47 have attracted interest from the viewpoint of mechanical properties because the ABA triblock copolymers possess good elastomeric property due to...…”

Section: Introductionmentioning

confidence: 99%

Versatile Controls of Microdomain Morphologies and Temperature Dependencies in Lamellar Spacing by Blending Diblock Copolymers Bearing Antisymmetric Compositions

et al. 2017

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The morphologies of the microphase-separated structures in the binary blends of diblock copolymers (AB/AB) have been studied intensively for the case of diblock copolymers bearing antisymmetric compositions with similar molecular weights. Here, the two diblock copolymers 1 and 2, of which compositions are 0.5 – x and 0.5 + x (0 < x < 0.5), respectively, were blended, and the morphology diagram was constructed in the plot of χ Z vs the average composition of the A component, where χ is the interaction parameter between A and B segments and Z is the average degree of polymerization of the two AB diblock copolymers. The temperature-dependent morphologies were analyzed by synchrotron small-angle X-ray scattering (SAXS) measurements. It was found that the morphology diagram agrees in principle with the theoretical one for the neat AB diblocks by Matsen and Bates ( Macromolecules 1996 , 29 , 1091–1098), although the disordered phase was a bit expanded in the experimentally determined morphology diagram. Anomalous temperature dependencies in the lamellar spacing have been also comprehensively studied for the binary blends of antisymmetric diblock copolymers as a function of the degree of compositional asymmetry by closely adjusting the average composition in the blend specimen at 0.50. For this purpose, more than 20 neat diblock copolymers have been synthesized with a wide range of compositions from 0.20 to 0.87 and a range of molecular weight of 12 000–33 800. The temperature dependencies of the lamellar spacing were also analyzed by synchrotron SAXS measurements. As a result, the following things were found. The scaling exponent α in D ∼ T α was still negative but slightly larger than the usual value (i.e., α = −0.33) for the smaller degree of asymmetry in the composition (i.e., x is small), while α became positive for the higher degree of asymmetry. The latter result is very anomalous because the temperature dependence is opposite (i.e., the lamellar spacing increases with an increase of temperature). The value of α was found to be linearly rationalized with the degree of asymmetry τ (which is especially introduced in the current paper for this purpose), for the binary blends with the average composition of 0.50. Based on this result, one can prepare lamellar microdomains, of which spacing does not change with temperature, by blending two diblock copolymers with τ = 1.33 (corresponding to 0.3 and 0.7 of compositions) having similar molecular weights. This would be important for manufacturing materials with properties (for instance, the optical property) independent of temperature. From the current study, the binary blends of the antisymmetric diblock copolymers are concluded to be versatile such that the precise controls of the morphologies and the temperat...

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A theoretical and simulation study of the self-assembly of a binary blend of diblock copolymers

Cited by 19 publications

References 32 publications

Phase diagrams of block copolymer melts by dissipative particle dynamics simulations

Phase diagrams of block copolymer melts by dissipative particle dynamics simulations

Topological Frustration as a New Parameter to Tune Morphology Revealed through Exploring the Continuum between A-B-C 3-Arm Star and Linear Triblock Polymers

Versatile Controls of Microdomain Morphologies and Temperature Dependencies in Lamellar Spacing by Blending Diblock Copolymers Bearing Antisymmetric Compositions

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