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Literature DB >> 25713371

Quantitative relations between cooperative motion, emergent elasticity, and free volume in model glass-forming polymer materials.

Beatriz A Pazmiño Betancourt¹, Paul Z Hanakata², Francis W Starr³, Jack F Douglas⁴.

Abstract

The study of glass formation is largely framed by semiempirical models that emphasize the importance of progressively growing cooperative motion accompanying the drop in fluid configurational entropy, emergent elasticity, or the vanishing of accessible free volume available for molecular motion in cooled liquids. We investigate the extent to which these descriptions are related through computations on a model coarse-grained polymer melt, with and without nanoparticle additives, and for supported polymer films with smooth or rough surfaces, allowing for substantial variation of the glass transition temperature and the fragility of glass formation. We find quantitative relations between emergent elasticity, the average local volume accessible for particle motion, and the growth of collective motion in cooled liquids. Surprisingly, we find that each of these models of glass formation can equally well describe the relaxation data for all of the systems that we simulate. In this way, we uncover some unity in our understanding of glass-forming materials from perspectives formerly considered as distinct.

Entities: Chemical

Keywords: cooperativity; elasticity; free volume; glass formation; strings

Year: 2015 PMID： 25713371 PMCID： PMC4364219 DOI： 10.1073/pnas.1418654112

Source DB: PubMed Journal: Proc Natl Acad Sci U S A ISSN： 0027-8424 Impact factor: 11.205

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