Individual chain dynamics of a polyethylene melt undergoing steady shear flow

Sefiddashti, Mohammad Hadi Nafar; Edwards, Brian J.; Khomami, Bamin

doi:10.1122/1.4903498

Cited by 95 publications

(190 citation statements)

References 55 publications

(136 reference statements)

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“…As noted in the introduction hints of ES are observed in molecular dynamics simulations of linear polymers [Sefiddashti et al (2015)] and in slip-link simulations [Masubuchi et al (2012[Masubuchi et al ( , 2014; Andreev et al (2013)]: These methods may provide corroboration of the assumptions in the present model for branched polymers. A more detailed tube model description of branched polymer dynamics might seek to capture the nested tube structure suggested by constraint release models, and to couple the dynamics of adjacent polymer segments in a branched molecule.…”

Section: Discussionsupporting

confidence: 74%

“…There are also indications of ES in recent computer simulation, e.g., the work of Sefiddashti et al (2015). However, in the context of branched polymers and the pom-pom model, the effects of ES are potentially very strong: (i) The onset of branch-point withdrawal within the model provides an occasion for a sudden and rapid increase in the amount of ES.…”

Section: Introductionmentioning

confidence: 99%

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Modifying the pom-pom model for extensional viscosity overshoots

Hawke¹,

Huang²,

Hassager³

et al. 2015

Journal of Rheology

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We have developed a variant of the pom-pom model that qualitatively describes two surprising features recently observed in filament stretching rheometer experiments of uniaxial extensional flow of industrial branched polymer resins: (i) Overshoots of the transient stress during steady flow and (ii) strongly accelerated stress relaxation upon cessation of the flow beyond the overshoot. Within the context of our model, these overshoots originate from entanglement stripping (ES) during the processes of normal chain retraction and branch point withdrawal. We demonstrate that, for a single mode, the predictions of our overshoot model are qualitatively consistent with experimental data. To provide a quantitative fit, we represent an industrial melt by a superposition of several individual modes. We show that a minimal version of our model, in which ES due to normal chain retraction is omitted, can provide a reasonable, but not perfect, fit to the data. With regard the stress relaxation after (kinematically) steady flow, we demonstrate that the differential version of tube orientation dynamics in the original pom-pom model performs anomalously. We discuss the reasons for this and suggest a suitable alternative. V C 2015 The Society of Rheology.[http://dx

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Section: Discussionsupporting

confidence: 74%

Section: Introductionmentioning

confidence: 99%

Modifying the pom-pom model for extensional viscosity overshoots

Hawke¹,

Huang²,

Hassager³

et al. 2015

Journal of Rheology

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“…Costanzo et al 7) proposed the tumbling motion of entangled polymers, an unexpected molecular mechanism just discovered in the nonequilibrium molecular dynamics simulations of Nafar Sefiddashti et al 9) . Inspired by the damped oscillations shown in the end-to-end vector autocorrelation function, as observed by Nafar Sefiddashti et al 9) at the steady state of fast shear flows, Costanzo et al 7) introduced a damped oscillating tumbling function into the equation for the chain stretch dynamics, while leaving unaltered the equation for the orientation dynamics.…”

Section: Introductionmentioning

confidence: 91%

“…Inspired by the damped oscillations shown in the end-to-end vector autocorrelation function, as observed by Nafar Sefiddashti et al 9) at the steady state of fast shear flows, Costanzo et al 7) introduced a damped oscillating tumbling function into the equation for the chain stretch dynamics, while leaving unaltered the equation for the orientation dynamics. Such a simplified approach, however, has been recently questioned in a second paper by Nafar Sefiddashti et al 10) , who analyzed nonequilibrium molecular dynamics simulations also under transient startup of fast shear flows, revealing undershoots.…”

Section: Introductionmentioning

confidence: 99%

Stress Undershoot of Entangled Polymers under Fast Startup Shear Flows in Primitive Chain Network Simulations

Masubuchi

Ianniruberto

Marrucci

2018

J. Soc. Rheol., Jpn

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In this study, viscosity growth of entangled polymers under startup of fast shear flows was investigated by means of primitive chain network simulations. In particular, we focused on the undershoot following the well-known overshoot. The simulations reasonably reproduced the viscosity growth data reported in the literature for polystyrene melts. To investigate the origin of the observed undershoot, stress was decomposed into orientational and stretch contributions through a decoupling approximation. The decoupled results show a tiny undershoot in both orientation and stretch. Molecular tumbling was also monitored, both for single molecules and in terms of an average end-to-end orientation angle. Results appear to confirm that tumbling causes the viscosity undershoot, consistently with the suggestion of Costanzo et al. [Macromolecules, 2016, 49, 3915].

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“…These simulations thus revealed that inclusion of constraint release events played an important role in the emergence of the plateau region and concomitant mitigation of the drop in stress, as predicted by the DE theory. Recent atomistic simulations of unentangled [15] and mildly entangled [16] polyethylene (PE) melts showed that individual chains experience retraction and rotation cycles within oriented tubelike structures formed by highly stretched surrounding chain molecules at large strain rates. The onset of chain rotation was attributed to the flowinduced disentanglement of polymer chains that occurs at high shear rates in steady shearing flow [16].…”

Section: Introductionmentioning

confidence: 99%

Steady shearing flow of a moderately entangled polyethylene liquid

Sefiddashti¹,

Edwards²,

Khomami³

2016

Journal of Rheology

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105

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The rheological properties and dynamical responses of a monodisperse polyethylene (PE) liquid, C 700 H 1402 , were examined using equilibrium molecular dynamics and nonequilibrium molecular dynamics simulations of the atomistically detailed molecules. Equilibrium structural and dynamical properties of the PE liquid, such as the disengagement time (s d ), Rouse time (s R ), entanglement time, (s e ), reptation tube diameter, number of entanglements, and the distribution of the chain end-to-end vector, each followed very closely the predictions of the Doi and Edwards theory. Under steady shear conditions, the rheological and dynamical responses exhibited starkly different behavior as functions of shear rate, which could be categorized within four distinct shear rate regions; namely,In the first region, the topological properties of the liquid remained relatively unperturbed from quiescent conditions and the rheological characteristic functions remained constant throughout. Little in the way of chain orientation or stretching occurred, and reptation theory described very well the system properties. Within the second range, chain orientation became the dominant dynamical system response with only a slight degree of chain stretching being evident. Rheological characteristic functions displayed shear-thinning behavior, and a plateau in the shear stress profile was observed. In the third range, significant chain stretching became apparent which led to a dramatic reduction in the number of entanglements, thereby enabling a rotational motion of the individual chain molecules in response to the vorticity of the shear field. A new timescale became evident that was associated with the period of the rotation/retraction cycles of the individual molecules. In the fourth region, the rotational motion of the chains became the sole relaxation mode of the system as the number of entanglements was gradually reduced to a level too low to support the conventional reptation theory. Furthermore, the individual molecular motions shared the same characteristics as those of similar chains in dilute and semidilute solution. Comparisons of the corresponding structural and dynamical properties of the C 700 H 1402 liquid with those of the mildly entangled PE liquid C 400 H 802 revealed how the properties of the liquids scaled with chain length. V C 2016 The Society of Rheology. [http://dx.

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Individual chain dynamics of a polyethylene melt undergoing steady shear flow

Cited by 95 publications

References 55 publications

Modifying the pom-pom model for extensional viscosity overshoots

Modifying the pom-pom model for extensional viscosity overshoots

Stress Undershoot of Entangled Polymers under Fast Startup Shear Flows in Primitive Chain Network Simulations

Steady shearing flow of a moderately entangled polyethylene liquid

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