Mechanical properties of high-performance elastomeric nanocomposites: a sequential mesoscale simulation approach

Deng, Shengwei; Huang, Yongmin; Xu, Shouhong; Lin, Shaoliang; Liu, Honglai; Hu, Ying

doi:10.1039/c4ra10016f

Cited by 9 publications

(3 citation statements)

References 41 publications

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“…In ref , the author uses coarse-grained simulations based on iterative Boltzmann applied to a model system of silica nanoparticles embedded in atactic polystyrene to study the structural and dynamic properties of the interfacial region and its dependency on different parameters such as the matrix and grafted polymer chain length, grafting density, and so forth. In ref , the authors combine a morphological model based on density functional theory, with a micromechanical model to relate the mechanical response of complex polymer nanocomposites without large-scale computations. This, in principle, is the same type of integration followed in this work, albeit based on different approaches to both the morphology and the mechanics.…”

Section: Introductionmentioning

confidence: 99%

“…This, in principle, is the same type of integration followed in this work, albeit based on different approaches to both the morphology and the mechanics. In addition, the author’s focus in ref is on general concepts such as the hardening effect of nanoparticles integrated inside soft or hard polymer domains. In ref , the authors use atomistic modeling in large-scale molecular dynamics simulations of sulfur-cured polybutadiene (PB) and nanosilica-filled PB composites.…”

Section: Introductionmentioning

confidence: 99%

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Mesoscopic Model for the Simulation of Dynamic Mechanical Properties of Filled Elastomers: Model Construction and Parameterization

Viktorova

Hentschke

Fleck

et al. 2020

ACS Appl. Polym. Mater.

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We describe a modeling approach to the calculation of dynamic moduli of filled elastomers based on filler morphologies derived from experimental interface tensions of the material's components. A Monte Carlo morphology generator is used to build model compounds on the micrometer scale. Subsequently, the Monte Carlo morphologies are mapped onto a topologically identical bead-spring model, allowing to compute the amplitude and frequency dependence of the dynamic moduli during cyclic deformations. The combination of a Monte Carlo approach to filler flocculation with a finite element-like force equilibrium model ties the experimental surface tensions, characterizing the individual components, to the dynamic behavior of the macroscopic material. Here, we discuss the model and its parameterization using the example of a filled nanocomposite with two components. The predictive capabilities of the model are illustrated in terms of storage modulus and tan δ, including their dependence on strain frequency and filler concentration, for selected examples.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Mesoscopic Model for the Simulation of Dynamic Mechanical Properties of Filled Elastomers: Model Construction and Parameterization

Viktorova

Hentschke

Fleck

et al. 2020

ACS Appl. Polym. Mater.

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“…The simulation of heterogeneous materials by LSM is achieved through assigning force constants to individual bonds depending upon the composition on each grid and thereby avoiding complicated mesh generation in FEM. However, the Born LSM adopted in this work [32,33] is only valid under small strain, and the input structure is considered as the equilibrium structure, where the LSM cannot be used to study the micro-structural evolution. Therefore, micro-scale or meso-scale simulation methods (such as molecular dynamics (MD) simulation [34]) are required to study the spatial organization of particles.…”

Section: Introductionmentioning

confidence: 99%

Multiscale Simulation of Branched Nanofillers on Young’s Modulus of Polymer Nanocomposites

Deng

2018

Polymers

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Nanoscale tailoring the filler morphology in experiment offers new opportunities to modulate the mechanical properties of polymer nanocomposites. Based on the conventical rod and experimentally available tetrapod filler, I compare the nanofiller dispersion and elastic moduli of these two kinds of nanocomposites via molecular dynamics simulation and a lattice spring model. The results show that the tetrapod has better dispersion than the rod, which is facilitate forming the percolation network and thus benefitting the mechanical reinforcement. The elastic modulus of tetrapod filled nanocomposites is much higher than those filled with rod, and the modulus disparity strongly depends on the aspect ratio of fillers and particle-polymer interaction, which agrees well with experimental results. From the stress distribution analysis on single particles, it is concluded that the mechanical disparity between bare rod and tetrapod filled composites is due to the effective stress transfer in the polymer/tetrapod composites.

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Exploration of the Structure–Property Relationship of Polymer‐Based Composites by Monte‐Carlo‐Coupled Viscoelastic Lattice Spring Model

Cui

Huang

2021

Advcd Theory and Sims

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A viscoelastic lattice spring model is applied to real polymer blend containing strong interaction, i.e., chemical bond, to investigate the structure–property correlation in combination of Monte Carlo method modified by cavity diffusion and bond length fluctuation algorithms. Impacts of inclusion ratio, chemical bonds, chain length, and interface orientation on the mechanical response along with fracture mode are quantified through simulation of uniaxial tensile test. It is confirmed that introduction of strong interaction and prolongation in chain length induces observable reinforcement in global modulus and ultimate tensile strength, respectively, and the amplification is more significant when the interface is parallel to external load.

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Mechanical properties of high-performance elastomeric nanocomposites: a sequential mesoscale simulation approach

Cited by 9 publications

References 41 publications

Mesoscopic Model for the Simulation of Dynamic Mechanical Properties of Filled Elastomers: Model Construction and Parameterization

Mesoscopic Model for the Simulation of Dynamic Mechanical Properties of Filled Elastomers: Model Construction and Parameterization

Multiscale Simulation of Branched Nanofillers on Young’s Modulus of Polymer Nanocomposites

Exploration of the Structure–Property Relationship of Polymer‐Based Composites by Monte‐Carlo‐Coupled Viscoelastic Lattice Spring Model

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