Detailed Atomistic Molecular Dynamics Simulation of <i>cis</i>-1,4-Poly(butadiene)

Tsolou, Georgia; Mavrantzas, Vlasis G.; Theodorou, Doros N.

doi:10.1021/ma0491210

Cited by 126 publications

(185 citation statements)

References 66 publications

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“…The present work complements these studies by extending the MD simulations for a model C 128 cis-1,4-PB system to somewhat lower temperatures (down to 165 K) and by analyzing also: (a) the time autocorrelation function of each Rouse mode [32] X p along the simulated C 128 cis-1,4-PB chain, and (b) the coherent [33][34][35] and incoherent [36,37] dynamic structure factors for different values of the magnitude q of the wavevector. Our results for the incoherent dynamic structure factor are then directly compared with available data obtained from NS measurements for the dependence of the incoherent relaxation times on q.…”

Section: Introductionmentioning

confidence: 73%

Molecular dynamics simulation of temperature and pressure effects on the intermediate length scale dynamics and zero shear rate viscosity of cis-1,4-polybutadiene: Rouse mode analysis and dynamic structure factor spectra

Tsolou¹,

Harmandaris²,

Mavrantzas³

2008

Journal of Non-Newtonian Fluid Mechanics

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Section: Introductionmentioning

confidence: 73%

Molecular dynamics simulation of temperature and pressure effects on the intermediate length scale dynamics and zero shear rate viscosity of cis-1,4-polybutadiene: Rouse mode analysis and dynamic structure factor spectra

Tsolou¹,

Harmandaris²,

Mavrantzas³

2008

Journal of Non-Newtonian Fluid Mechanics

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“…We have applied our methodology to atomistic MD simulation trajectories accumulated in the recent past 24,25 for a number of model linear PE and PB melts: C 320 , C 400 , and C 500 PE melts ͑denoted as PE320, PE400, and PE500, respectively͒, C 320 , C 400 , and C 800 cis-1,4-PB ͑denoted as PBcis320, PB-cis400 and PB-cis800, respectively͒ and C 320 and C 400 trans-1,4-PB melts ͑denoted as PB-trans320, and PBtrans400, respectively͒. All PE and trans-1,4-PB systems and the PB-cis800 system are strictly monodisperse ͑polydis-persity index I =1͒, whereas the PB-cis320 and PB-cis400 systems are slightly polydisperse ͑I = 1.08 and I = 1.05 for PB-cis320 and PB-cis400, respectively͒.…”

Section: Resultsmentioning

confidence: 99%

Quantifying chain reptation in entangled polymer melts: Topological and dynamical mapping of atomistic simulation results onto the tube model

Stephanou

Baig

Tsolou

et al. 2010

The Journal of Chemical Physics

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153

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Articles you may be interested inTemperature dependent micro-rheology of a glass-forming polymer melt studied by molecular dynamics simulation J. Chem. Phys. 141, 124907 (2014) The topological state of entangled polymers has been analyzed recently in terms of primitive paths which allowed obtaining reliable predictions of the static ͑statistical͒ properties of the underlying entanglement network for a number of polymer melts. Through a systematic methodology that first maps atomistic molecular dynamics ͑MD͒ trajectories onto time trajectories of primitive chains and then documents primitive chain motion in terms of a curvilinear diffusion in a tubelike region around the coarse-grained chain contour, we are extending these static approaches here even further by computing the most fundamental function of the reptation theory, namely, the probability ͑s , t͒ that a segment s of the primitive chain remains inside the initial tube after time t, accounting directly for contour length fluctuations and constraint release. The effective diameter of the tube is independently evaluated by observing tube constraints either on atomistic displacements or on the displacement of primitive chain segments orthogonal to the initial primitive path. Having computed the tube diameter, the tube itself around each primitive path is constructed by visiting each entanglement strand along the primitive path one after the other and approximating it by the space of a small cylinder having the same axis as the entanglement strand itself and a diameter equal to the estimated effective tube diameter. Reptation of the primitive chain longitudinally inside the effective constraining tube as well as local transverse fluctuations of the chain driven mainly from constraint release and regeneration mechanisms are evident in the simulation results; the latter causes parts of the chains to venture outside their average tube surface for certain periods of time. The computed ͑s , t͒ curves account directly for both of these phenomena, as well as for contour length fluctuations, since all of them are automatically captured in the atomistic simulations. Linear viscoelastic properties such as the zero shear rate viscosity and the spectra of storage and loss moduli obtained on the basis of the obtained ͑s , t͒ curves for three different polymer melts ͑polyethylene, cis-1,4-polybutadiene, and trans-1,4-polybutadiene͒ are consistent with experimental rheological data and in qualitative agreement with the double reptation and dual constraint models. The new methodology is general and can be routinely applied to analyze primitive path dynamics and chain reptation in atomistic trajectories ͑accumulated through long MD simulations͒ of other model polymers or polymeric systems ͑e.g., bidisperse, branched, grafted, etc.͒; it is thus believed to be particularly useful in the future in evaluating proposed tube models and developing more accurate theories for entangled systems.

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“…[4][5][6][7][8] On the microscopic level, atomistic molecular dynamics simulations have been used for the prediction of chain diffusion of polymers with simple chemical structure, like polyethylene or polybutadiene, and with low molecular weight. [8][9][10] However, because of the broad range of length and time scales characterizing macromolecules, application of these techniques to systems with high molecular weight or to polymers with more complicated structure is not possible in most cases. 5,6,[8][9][10][11] For this reason and in order to increase the length and time scales accessible by simulations coarse-grained (CG) models have proven to be very efficient.…”

Section: Introductionmentioning

confidence: 99%

“…42 In addition, atomistic MD simulations of polyethylene 8,9 and polybutadiene 10 show an exponent of about 2.3 for slightly entangled melts.…”

mentioning

confidence: 99%

Dynamics of Polystyrene Melts through Hierarchical Multiscale Simulations

2009

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A quantitative understanding and prediction of the dynamics of entangled polymer melts is a long-standing problem. In this work we present results about the dynamical and rheological properties of atactic polystyrene melts, obtained from a hierarchical approach that combines atomistic and coarse-grained dynamic simulations of unentangled and entangled systems. By comparing short chain atomistic and coarse-grained simulations, the time mapping constant is determined. Self-diffusion coefficients, after correcting for the chain end free volume effect, show a transition from Rouse to reptation-like behavior. In addition, the entanglement molecular weight is calculated through a primitive path analysis. All properties are compared to experimental data.

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Detailed Atomistic Molecular Dynamics Simulation of cis-1,4-Poly(butadiene)

Cited by 126 publications

References 66 publications

Molecular dynamics simulation of temperature and pressure effects on the intermediate length scale dynamics and zero shear rate viscosity of cis-1,4-polybutadiene: Rouse mode analysis and dynamic structure factor spectra

Molecular dynamics simulation of temperature and pressure effects on the intermediate length scale dynamics and zero shear rate viscosity of cis-1,4-polybutadiene: Rouse mode analysis and dynamic structure factor spectra

Quantifying chain reptation in entangled polymer melts: Topological and dynamical mapping of atomistic simulation results onto the tube model

Dynamics of Polystyrene Melts through Hierarchical Multiscale Simulations

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