Star polymers confined in a nanoslit: a simulation test of scaling and self-consistent field theories

Paturej, Jarosław; Milchev, A.; Егоров, С. А.; Binder, Kurt

doi:10.1039/c3sm51275d

Cited by 17 publications

(22 citation statements)

References 60 publications

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“…The main parameters of the SPB are the number of chains f and the number of monomers per chain N c ; colloid diameter is where is the monomer diameter. Like in a related study 46 , steric monomer-monomer and monomer-colloid interaction is described by the Weeks-Chandler-Andersen (WCA) repulsion 47 and the bonds are modelled by the finite extensible nonlinear elastic (FENE) potential tuned such that the bonds do not cross. Our implicit-solvent scheme and this particular choice of interactions are both consistent with the good solvent conditions studied here.…”

Section: Methodsmentioning

confidence: 99%

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Elasticity of polymeric nanocolloidal particles

Riest

Athanasopoulou

Егоров

et al. 2015

Sci Rep

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Softness is an essential mechanical feature of macromolecular particles such as polymer-grafted nanocolloids, polyelectrolyte networks, cross-linked microgels as well as block copolymer and dendrimer micelles. Elasticity of individual particles directly controls their swelling, wetting, and adsorption behaviour, their aggregation and self-assembly as well as structural and rheological properties of suspensions. Here we use numerical simulations and self-consistent field theory to study the deformation behaviour of a single spherical polymer brush upon diametral compression. We observe a universal response, which is rationalised using scaling arguments and interpreted in terms of two coarse-grained models. At small and intermediate compressions the deformation can be accurately reproduced by modelling the brush as a liquid drop, whereas at large compressions the brush behaves as a soft ball. Applicable far beyond the pairwise-additive small-strain regime, the models may be used to describe microelasticity of nanocolloids in severe confinement including dense disordered and crystalline phases.

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Section: Methodsmentioning

confidence: 99%

“…The self-consistent field (SCF) theory was implemented on a cubic lattice using the Scheutjens-Fleer scheme 46 50 . We chose to represent the walls by a hard rather than Yukawa potential like in MD simulation.…”

Section: Methodsmentioning

confidence: 99%

Elasticity of polymeric nanocolloidal particles

Riest

Athanasopoulou

Егоров

et al. 2015

Sci Rep

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“…28 Recent simulations on polymers in confined space have not addressed intramolecular polymer complexation. [29][30][31]51 Hence, simulations are regarded within this manuscript to understand the interfacial properties of PPO-b-PDMAEMA.…”

Section: Introductionmentioning

confidence: 99%

Interface-enforced complexation between copolymer blocks

Steinschulte

Draber

et al. 2015

Soft Matter

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Binary diblock copolymers and corresponding ternary miktoarm stars are studied at oil-water interfaces. All polymers contain oil-soluble poly(propylene oxide) PPO, water-soluble poly(dimethylaminoethyl methacrylate) PDMAEMA and/or poly(ethylene oxide) PEO. The features of their Langmuir compression isotherms are well related to the ones of the corresponding homopolymers. Within the Langmuir-trough, PEO-b-PPO acts as the most effective amphiphile compared to the other PPO-containing copolymers. In contrast, the compression isotherms show a complexation of PPO and PDMAEMA for PPO-b-PDMAEMA and the star, reducing their overall amphiphilicity. Such complex formation between the blocks of PPO-b-PDMAEMA is prevented in bulk water but facilitated at the interface. The weakly-interacting blocks of PPO-b-PDMAEMA form a complex due to their enhanced proximity in such confined environments. Scanning force microscopy and Monte Carlo simulations with varying confinement support our results, which are regarded as compliant with the mathematical random walk theorem by Pólya. Finally, the results are expected to be of relevance for e.g. emulsion formulation and macromolecular engineering.

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“…As deformation progresses, the constraint of a chain and therefore its tube diameter deforms from the motion of surrounding chains. It should be addressed that we use Flory-type free energy to build our model, which can be further improved by incorporating blob concepts [22]. As in classical continuum mechanics, let us consider a body Ω 0 with its boundary ∂Ω 0 .…”

Section: Modeling Variable Chain Confinement In Polymers 21 Polymer mentioning

confidence: 99%

Variable Chain Confinement in Polymers With Nanosized Pores and Its Impact on Instability

Tang

Greene

Liu

et al. 2015

Journal of Applied Mechanics

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Recent experiments and molecular dynamics simulations have proven that polymer chains are less confined in layers near the free surfaces of submicro-nano sized pores. A recent model has incorporated this observed variable chain confinement at void surfaces in a mechanism-based hyperelastic model. This work employs that model to do two things: explain the large discrepancy between classical homogenization theories and physical experiments measuring the modulus of nano-porous polymers, and describe instability behavior (onset and postinstability deformation) of this class of materials. The analysis demonstrates that less confinement of polymer chains near free surfaces of voids inhibits tilting buckling while promoting pattern transformation. The sensitivity of geometric instability modes to void size is also studied in depth, helping lay the foundation for fabricating solids with tunable acoustic and optical properties. The simulation approach outlined provides experimentalists with a practical route to estimate the thickness of the interfacial layer in nano-porous polymers.

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Star polymers confined in a nanoslit: a simulation test of scaling and self-consistent field theories

Cited by 17 publications

References 60 publications

Elasticity of polymeric nanocolloidal particles

Elasticity of polymeric nanocolloidal particles

Interface-enforced complexation between copolymer blocks

Variable Chain Confinement in Polymers With Nanosized Pores and Its Impact on Instability

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