Systematic and simulation-free coarse graining of homopolymer melts: a relative-entropy-based study

Yang, Delian; Wang, Qiang

doi:10.1039/c5sm01142f

Cited by 11 publications

(7 citation statements)

References 40 publications

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“…PRISM theory has no mean-field or incompressibility assumptions and captures density fluctuations over a range of length scales. It has been successfully applied to predict liquid structure in a broad range of soft-materials systems including melts, ,, blends, ,, nanocomposites, ,− and polyelectrolytes. , Besides the prediction of structure and thermodynamics, PRISM theory has also been useful as a coarse-graining engine − and for providing models for experimental scattering data. , We only provide a brief overview of this theory in this paper and direct the reader to previous papers cited above for additional details.…”

Section: Approachmentioning

confidence: 99%

Effect of Polymer Architecture on the Structure and Interactions of Polymer Grafted Particles: Theory and Simulations

2017

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We use Langevin dynamics simulations and Polymer Reference Interaction Site Model (PRISM) theory to study polymer grafted nanoparticles specifically to explain the impact of comb polymer architecture on the grafted layer structure and effective interparticle interactions in solvent and in matrix polymer. First, we use simulations to study a single particle grafted with comb polymers with varying comb polymer design (i.e., spacing and length of side chains along the comb polymer backbone), grafting density (i.e., polymer chains/particle surface area), and particle curvature in implicit solvent at the athermal limit. We find that increasing side chain length or decreasing side chain spacing along the comb polymer effectively swells and extends the polymer backbone due to the increasing side chain monomer crowding. For particles at finite curvature with increasing side chain monomer crowding, the monomer concentration profile of the comb polymer backbone at short distances from the surface resembles the concentration profile of a semiflexible linear polymer and at farther distances resembles that of flexible linear polymers grafted to a flat surface. As the particle curvature decreases to zero (i.e., flat surface), increasing side chain crowding has a simpler effect of expanding the grafted layer without changing the overall shape of the concentration profile. To understand how architecture affects the interactions of the comb polymer grafted particles, we use PRISM theory to calculate the potential of mean force (PMF) between comb polymer grafted particles in implicit solvent, explicit solvent, and explicit matrix of athermal linear polymers. On the basis of the PMFs calculated for a wide range of design parameters (grafting density, comb polymer design), we find that, compared to linear polymers, the comb polymers exhibit stronger effective attraction in the PMF between the grafted particles in both small molecule solvent and polymer matrix due to the increased crowding in the grafted layer from the comb polymer side chains. Interestingly, the PMF between the grafted particles in a small molecule solvent is more sensitive to the comb polymer design (i.e., side chain length and spacing) than the PMF between the grafted particles in a polymer matrix.

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Section: Approachmentioning

confidence: 99%

Effect of Polymer Architecture on the Structure and Interactions of Polymer Grafted Particles: Theory and Simulations

2017

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“…Bilinois et al 222 have proposed an alternative optimization route using stochastic algorithms. Relative entropy has thus been successfully deployed to model polymers in melts, 223 solution, 224 and heterogeneous environments. 185…”

Section: Relative Entropymentioning

confidence: 99%

Chemically specific coarse‐graining of polymers: Methods and prospects

Dhamankar

Webb

2021

Journal of Polymer Science

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Coarse-grained (CG) modeling is an invaluable tool for the study of polymers and other soft matter systems due to the span of spatiotemporal scales that typify their physics and behavior. Given continuing advancements in experimental synthesis and characterization of such systems, there is ever greater need to leverage and expand CG capabilities to simulate diverse soft matter systems with chemical specificity. In this review, we discuss essential modeling techniques, bottom-up coarse-graining methodologies, and outstanding challenges for the chemically specific CG modeling of polymer-based systems. This methodologically oriented discussion is complemented by representative literature examples for polymer simulation; we also offer some advisory practical considerations that should be useful for new researchers. Given its growing importance in the modeling and polymer science community, we further highlight some recent applications of machine learning that enhance CG modeling strategies. Overall, this review provides comprehensive discussion of methods and prospects for the chemically specific coarse-graining of polymers.

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“…In addition to making structural and thermodynamic predictions, PRISM has been applied as a coarse-graining engine to derive simplified force fields from the results of atomistic (or less coarse-grained) simulations. − Broadly, this approach consists of using noninteracting “ghost” sites to track the global correlations of groups of atoms or sites on a molecule. These group correlations can then be combined with closure relations to derive effective, coarse-grained pair potentials that reproduce the thermodynamics and structure of the more detailed system.…”

Section: Introductionmentioning

confidence: 99%

“…One example of this approach is called Integral Equation Coarse Graining (IECG). ,,− Despite some questions raised about the thermodynamic consistency of this method, recent work has served to support IECG’s accuracy when used correctly. References , − , and present detailed discussions on this IECG method and the proof of its thermodynamic consistency. Overall, using PRISM to create coarse-grained representations of polymer systems represents a unique and powerful use of the theory beyond structural and thermodynamic predictions.…”

Section: Introductionmentioning

confidence: 99%

pyPRISM: A Computational Tool for Liquid-State Theory Calculations of Macromolecular Materials

et al. 2018

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The Polymer Reference Interaction Site Model (PRISM) theory describes the equilibrium spatial correlations of liquid-like polymer systems including melts, blends, solutions, block copolymers, ionomers, liquid crystalline polymers, and nanocomposites. Using PRISM theory, one can calculate thermodynamic (second virial coefficients, Flory−Huggins χ interaction parameters, potentials of mean force) and structural (pair correlation functions, structure factors) data for these macromolecular materials. Here, we present a Python-based, open-source framework, pyPRISM, for conducting PRISM theory calculations. This framework aims to simplify PRISM-based studies by providing a user-friendly scripting interface for setting up and numerically solving the PRISM equations. pyPRISM also provides data structures, functions, and classes that streamline PRISM calculations, allowing pyPRISM to be extended for use in other tasks, such as the coarse-graining of atomistic simulation force fields or the modeling of experimental scattering data. The goals of this framework are to reduce the barrier to correctly and appropriately using PRISM theory and to provide a platform for rapid calculations of the structure and thermodynamics of polymeric fluids and nanocomposites.

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Systematic and simulation-free coarse graining of homopolymer melts: a relative-entropy-based study

Cited by 11 publications

References 40 publications

Effect of Polymer Architecture on the Structure and Interactions of Polymer Grafted Particles: Theory and Simulations

Effect of Polymer Architecture on the Structure and Interactions of Polymer Grafted Particles: Theory and Simulations

Chemically specific coarse‐graining of polymers: Methods and prospects

pyPRISM: A Computational Tool for Liquid-State Theory Calculations of Macromolecular Materials

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