Direct Measurement of Molecular Mobility in Actively Deformed Polymer Glasses

Lee, Hau-Nan; Paeng, Keewook; Swallen, Stephen F.; Ediger, M. D.

doi:10.1126/science.1165995

Cited by 263 publications

(439 citation statements)

References 27 publications

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“…31,35 The reason is that the Eyring equation does not take into account the extra shift of the energy barriers with stress due to the flow of the cage itself; the latter leads to stronger acceleration of the dynamics, ultimately leading to yield. 76 The solid-or liquid-like response of the material to the applied stress and hence the validity of eq 7 depends both on the thermal relaxation time τ P 2 and on the strain rate γ.…”

Section: Resultsmentioning

confidence: 99%

“…Following earlier studies 35 we use the rotational relaxation time τ P 2 as the τ R in eq 7. According to Eyring's approach, the applied stress produces linear shifts of the energy barriers surrounding a monomer, thus enhancing monomer diffusion in the direction of stress.…”

Section: Resultsmentioning

confidence: 99%

“…29 Recently, a strong decrease of relaxation times of a lightly cross-linked PMMA was shown upon deformation below the yield point. 35 Moreover, the increase of mobility was found to be stronger for higher strain rates. 31 In the case of high filler volume fractions, the polymers are strongly confined between neighboring filler particles.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Confinement-Induced Stiffening of Thin Elastomer Films: Linear and Nonlinear Mechanics vs Local Dynamics

2014

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Constant-pressure molecular-dynamics simulations have been carried out of a bead−rod model polymer confined between two attractive crystalline substrates. Three different substrate−substrate separations (i.e., film thicknesses) were used and two different polymer−substrate interaction strengths. The density profiles show a monomer layering close to the polymer− substrate interface. A higher density was found in this region compared to the middle bulklike layers of the films. The dependence of the film-averaged density on temperature and thickness was measured for all polymer films. Decreasing the film thickness leads to an increase of this density and of the film-averaged glass-transition temperature. Layer-resolved analysis of the segmental dynamics of the thickest films shows a gradient of the mobility upon approach of the polymer−substrate interface, while the middle-layer dynamics exhibits bulklike behavior. With decreasing film thickness, these gradients become overlapping. All polymer films were deformed uniaxially normal to the substrates beyond their linear viscoelastic regime; their elastic moduli but also their secant moduli at larger strain amplitudes were extracted. In the linear regime, the stiffness was found to increase with decreasing film thickness; this correlates well with the layer-resolved segmental dynamical behavior. A strong drop of the stiffness was observed upon increasing the deformation amplitude; this drop was more pronounced for stiffer films. It is shown that the drop in stiffness can be qualitatively explained by the drop of the relaxation times as well as by the increased heterogeneity of the dynamics in different film layers upon deformation. The thickness dependencies of the structural, dynamical, and mechanical properties become more pronounced with stronger adsorption to the substrates.

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

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Confinement-Induced Stiffening of Thin Elastomer Films: Linear and Nonlinear Mechanics vs Local Dynamics

2014

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“…Here we show that a minimal model, combining just two key elements of any such theory (nonfactorable aging/rejuvenation, and the strain dependence of polymer-borne stresses), semiquantitatively explains many of the results reported in [3].…”

mentioning

confidence: 94%

“…Particularly striking is the evolution of the segmental relaxation time τ (t), controlling the rate of local rearrangements, when a load is applied. Recently, Lee et al [3,15] showed that τ (t) falls steadily during the early stages of elongational deformation, and then more sharply, reaching a small fraction ∼ 10 −3.3 of its initial level before dramatically rising again, as the local strain rate started to drop on entering the 'strain hardening' regime. While elements of this scenario have been confirmed in coarse-grained and molecular simulations [17][18][19][20], no convincing theoretical picture has yet emerged.…”

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confidence: 99%

Simple Model for the Deformation-Induced Relaxation of Glassy Polymers

2012

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Glassy polymers show "strain hardening": at constant extensional load, their flow first accelerates, then arrests. Recent experiments have found this to be accompanied by a striking and unexplained dip in the segmental relaxation time. Here we explain such behavior by combining a minimal model of flow-induced liquefaction of a glass, with a description of the stress carried by strained polymers, creating a non-factorable interplay between aging and strain-induced rejuvenation. Under constant load, liquefaction of segmental motion permits strong flow that creates polymer-borne stress. This slows the deformation enough for the segmental modes to re-vitrify, causing strain hardening.

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Similarities of the Collective Interfacial Dynamics of Grain Boundaries and Nanoparticles to Glass‐Forming Liquids

Zhang

Douglas²

2013

Liquid Polymorphism

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Direct Measurement of Molecular Mobility in Actively Deformed Polymer Glasses

Cited by 263 publications

References 27 publications

Confinement-Induced Stiffening of Thin Elastomer Films: Linear and Nonlinear Mechanics vs Local Dynamics

Confinement-Induced Stiffening of Thin Elastomer Films: Linear and Nonlinear Mechanics vs Local Dynamics

Simple Model for the Deformation-Induced Relaxation of Glassy Polymers

Similarities of the Collective Interfacial Dynamics of Grain Boundaries and Nanoparticles to Glass‐Forming Liquids

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