Mobility gradients yield rubbery surfaces on top of polymer glasses

Many emerging materials, such as ultrastable glasses 1 , 2 of interest for phone displays and OLED television screens, owe their properties to a gradient of enhanced mobility at the surface of glass-forming liquids. The discovery of this surface mobility enhancement 3 – 5 has reshaped our understand...

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Bibliographic Details
Published in:Nature (London) 2021-08, Vol.596 (7872), p.372-376
Main Authors: Hao, Zhiwei, Ghanekarade, Asieh, Zhu, Ningtao, Randazzo, Katelyn, Kawaguchi, Daisuke, Tanaka, Keiji, Wang, Xinping, Simmons, David S., Priestley, Rodney D., Zuo, Biao
Format: Article
Language:English
Subjects:
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142/136
639/301/923/1028
639/301/923/218
Breakdown
Chain dynamics
Chemical properties
Creep (materials)
Dependence
Elastomers
Engineering research
Glass
Humanities and Social Sciences
Interfaces
Macromolecules
Mobility
Molecular weight
multidisciplinary
Nanocomposites
Polymer physics
Polymeric composites
Polymers
Rheological properties
Rheology
Science
Science (multidisciplinary)
Surface boundary layer
Surface layers
Temperature
Thin films
Tribology
Viscoelasticity
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Summary:Many emerging materials, such as ultrastable glasses 1 , 2 of interest for phone displays and OLED television screens, owe their properties to a gradient of enhanced mobility at the surface of glass-forming liquids. The discovery of this surface mobility enhancement 3 – 5 has reshaped our understanding of the behaviour of glass formers and of how to fashion them into improved materials. In polymeric glasses, these interfacial modifications are complicated by the existence of a second length scale—the size of the polymer chain—as well as the length scale of the interfacial mobility gradient 6 – 9 . Here we present simulations, theory and time-resolved surface nano-creep experiments to reveal that this two-scale nature of glassy polymer surfaces drives the emergence of a transient rubbery, entangled-like surface behaviour even in polymers comprised of short, subentangled chains. We find that this effect emerges from superposed gradients in segmental dynamics and chain conformational statistics. The lifetime of this rubbery behaviour, which will have broad implications in constraining surface relaxations central to applications including tribology, adhesion, and surface healing of polymeric glasses, extends as the material is cooled. The surface layers suffer a general breakdown in time−temperature superposition (TTS), a fundamental tenet of polymer physics and rheology. This finding may require a reevaluation of strategies for the prediction of long-time properties in polymeric glasses with high interfacial areas. We expect that this interfacial transient elastomer effect and TTS breakdown should normally occur in macromolecular systems ranging from nanocomposites to thin films, where interfaces dominate material properties 5 , 10 . Surface enhancements in glass mobility are complicated in polymers by the interplay of the surface mobile layer thickness with a second length scale (the size of the polymer chains), giving rise to a transient rubbery surface even in polymers with short chains.
ISSN:0028-0836
1476-4687
DOI:10.1038/s41586-021-03733-7