Communication: One size fits all: Equilibrating chemically different polymer liquids through universal long-wavelength description

Zhang, Guojie; Stuehn, Torsten; Daoulas, Kostas Ch.; Kremer, Kurt

doi:10.1063/1.4922538

Cited by 21 publications

(42 citation statements)

References 29 publications

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“…We have represented their data of the branch point diffusion with red dots in Figure . Because of widespread universality in polymer physics, an apples‐to‐apples comparison is possible between the two models, provided we rescale the units of measurement. Our reference point is the first peak of the

g / t^{1 / 4}

curve, signaling the departure from reptation (linear chain dynamics), to structurally slower inter‐star dynamics.…”

Section: Resultsmentioning

confidence: 99%

5D Entanglement in Star Polymer Dynamics

Korolkovas

2018

Advcd Theory and Sims

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Star polymers are within the most topologically entangled macromolecules. For a star to move the current theory is that one arm must retract to the branch point. The probability of this event falls exponentially with molecular weight, and a quicker relaxation pathway eventually takes over. With a simulation over a hundred times faster than earlier studies, it is demonstrated that the mean square displacement scales with a power law 1/16 in time, instead of the previously assumed zero. It suggests that star polymer motion is the result of two linear relaxations coinciding in time. By analogy to linear polymers, which reptate with a random walk embedded in a 3D network, we show that star polymers relax by a random walk in a 5D network.

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g / t^{1 / 4}

curve, signaling the departure from reptation (linear chain dynamics), to structurally slower inter‐star dynamics.…”

Section: Resultsmentioning

confidence: 99%

5D Entanglement in Star Polymer Dynamics

Korolkovas

2018

Advcd Theory and Sims

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“…One famous example is the Kremer-Grest polymer model [128,129]. Zhang et al demonstrated that a melt of this phenomenological model can broadly be backmapped to many different types of homopolymers [130]. Everaers et al recently matched the generic large-scale behavior of Kremer-Grest simulations to chemistry-specific experiments via the Kuhn length [131].…”

Section: Compositional Samplingmentioning

confidence: 99%

Computational compound screening of biomolecules and soft materials by molecular simulations

Bereau

2021

Modelling Simul. Mater. Sci. Eng.

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Decades of hardware, methodological, and algorithmic development have propelled molecular dynamics (MD) simulations to the forefront of materialsmodeling techniques, bridging the gap between electronic-structure theory and continuum methods. The physics-based approach makes MD appropriate to study emergent phenomena, but simultaneously incurs significant computational investment. This topical review explores the use of MD outside the scope of individual systems, but rather considering many compounds. Such an in silico screening approach makes MD amenable to establishing coveted structure-property relationships. We specifically focus on biomolecules and soft materials, characterized by the significant role of entropic contributions and heterogeneous systems and scales. An account of the state of the art for the implementation of an MD-based screening paradigm is described, including automated force-field parametrization, system preparation, and efficient sampling across both conformation and composition. Emphasis is placed on machine-learning methods to enable MD-based screening. The resulting framework enables the generation of compound-property databases and the use of advanced statistical modeling to gather insight. The review further summarizes a number of relevant applications.

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“…The soft-sphere model proposed for the PS is motivated by arguments [22,29,30,32] based on general polymer physics. The model aims to capture long-wavelength conformational and structural properties of PS melts, accurately enough for performing backmapping at one state point.…”

Section: Model Descriptionmentioning

confidence: 99%

“…Melts with the sameN form a single class of materials which can be described [29] (in renormalized space) by a single blob-based model. This common model can be used to inter-convert [29] chemically different materials within the sameN -class. Increasing N b has two important consequences: a) the conformations of subchains approach the Gaussian statistics of ideal random-walks and b) the correlation hole of blobs becomes more shallow, i.e.…”

Section: Introductionmentioning

confidence: 99%

“…For both cases the small parameter controlling convergence is 1/ N b . Therefore, for large N b the interactions in blob-based models can be approximated by generic expressions [29][30][31][32] inspired by the ideal random-walk limit. Deviations from the asymptotic Gaussian behavior are taken implicitly into account by "renormalizing" the parameters in the generic expressions.…”

Section: Introductionmentioning

confidence: 99%

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Hierarchical modelling of polystyrene melts: from soft blobs to atomistic resolution

et al. 2019

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We demonstrate that hierarchical backmapping strategies incorporating generic blob-based models can equilibrate melts of high-molecular-weight polymers, described with chemically specific, atomistic, models. The central idea behind these strategies, is first to represent polymers by chains of large soft blobs (spheres) and efficiently equilibrate the melt on mesoscopic scale. Then, the degrees of freedom of more detailed models are reinserted step by step. The procedure terminates when the atomistic description is reached. Reinsertions are feasible computationally because the fine-grained melt must be re-equilibrated only locally. To develop the method, we choose a polymer with sufficient complexity. We consider polystyrene (PS), characterized by stereochemistry and bulky side groups. Our backmapping strategy bridges mesoscopic and atomistic scales by incorporating a blob-based, a moderately CG, and a united-atom model of PS. We demonstrate that the generic blob-based model can be parameterized to reproduce the mesoscale properties of a specific polymer -here PS. The moderately CG model captures stereochemistry. To perform backmapping we improve and adjust several fine-graining techniques. We prove equilibration of backmapped PS melts by comparing their structural and conformational properties with reference data from smaller systems, equilibrated with less efficient methods.

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Communication: One size fits all: Equilibrating chemically different polymer liquids through universal long-wavelength description

Cited by 21 publications

References 29 publications

5D Entanglement in Star Polymer Dynamics

5D Entanglement in Star Polymer Dynamics

Computational compound screening of biomolecules and soft materials by molecular simulations

Hierarchical modelling of polystyrene melts: from soft blobs to atomistic resolution

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