Dynamically Heterogeneous Relaxation of Entangled Polymer Chains

Yuecheng Zhou; Charles M. Schroeder

doi:10.1103/PhysRevLett.120.267801

Dynamically Heterogeneous Relaxation of Entangled Polymer Chains

Yuecheng Zhou
, Charles M. Schroeder

Research output: Contribution to journal › Article › peer-review

47 Scopus citations

Abstract

Stress relaxation following deformation of an entangled polymeric liquid is thought to be affected by transient reforming of chain entanglements. In this work, we use single molecule techniques to study the relaxation of individual polymers in the transition regime from unentangled to entangled solutions. Our results reveal the emergence of dynamic heterogeneity underlying polymer relaxation behavior, including distinct molecular subpopulations described by a single-mode and a double-mode exponential relaxation process. The slower double-mode timescale τd,2 is consistent with a characteristic reptation time, whereas the single-mode timescale τs and the fast double-mode timescale τd,1 are attributed to local regions of transient disentanglement due to deformation.

Original language	English (US)
Article number	267801
Journal	Physical review letters
Volume	120
Issue number	26
DOIs	https://doi.org/10.1103/PhysRevLett.120.267801
State	Published - Jun 26 2018
Externally published	Yes

All Science Journal Classification (ASJC) codes

General Physics and Astronomy

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10.1103/PhysRevLett.120.267801

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title = "Dynamically Heterogeneous Relaxation of Entangled Polymer Chains",

abstract = "Stress relaxation following deformation of an entangled polymeric liquid is thought to be affected by transient reforming of chain entanglements. In this work, we use single molecule techniques to study the relaxation of individual polymers in the transition regime from unentangled to entangled solutions. Our results reveal the emergence of dynamic heterogeneity underlying polymer relaxation behavior, including distinct molecular subpopulations described by a single-mode and a double-mode exponential relaxation process. The slower double-mode timescale τd,2 is consistent with a characteristic reptation time, whereas the single-mode timescale τs and the fast double-mode timescale τd,1 are attributed to local regions of transient disentanglement due to deformation.",

author = "Yuecheng Zhou and Schroeder, \{Charles M.\}",

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doi = "10.1103/PhysRevLett.120.267801",

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AU - Schroeder, Charles M.

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N2 - Stress relaxation following deformation of an entangled polymeric liquid is thought to be affected by transient reforming of chain entanglements. In this work, we use single molecule techniques to study the relaxation of individual polymers in the transition regime from unentangled to entangled solutions. Our results reveal the emergence of dynamic heterogeneity underlying polymer relaxation behavior, including distinct molecular subpopulations described by a single-mode and a double-mode exponential relaxation process. The slower double-mode timescale τd,2 is consistent with a characteristic reptation time, whereas the single-mode timescale τs and the fast double-mode timescale τd,1 are attributed to local regions of transient disentanglement due to deformation.

AB - Stress relaxation following deformation of an entangled polymeric liquid is thought to be affected by transient reforming of chain entanglements. In this work, we use single molecule techniques to study the relaxation of individual polymers in the transition regime from unentangled to entangled solutions. Our results reveal the emergence of dynamic heterogeneity underlying polymer relaxation behavior, including distinct molecular subpopulations described by a single-mode and a double-mode exponential relaxation process. The slower double-mode timescale τd,2 is consistent with a characteristic reptation time, whereas the single-mode timescale τs and the fast double-mode timescale τd,1 are attributed to local regions of transient disentanglement due to deformation.

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JO - Physical review letters

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Dynamically Heterogeneous Relaxation of Entangled Polymer Chains

Abstract

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