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Explaining the Sensitivity of Polymer Segmental Relaxation to Additive Size Based on the Localization Model

Thomas Q. McKenzie-Smith, Jack F. Douglas, Francis W. Starr

2021Physical Review Letters19 citationsDOI

Abstract

We use molecular simulations to examine how the dynamics of a coarse-grained polymer melt are altered by additives of variable size and interaction strength with the polymer matrix. The effect of diluent size σ on polymer dynamics changes significantly when its size is comparable to the polymer segment size. For each σ, we show that the localization model (LM) quantitatively describes the dependence of the segmental relaxation time τ on temperature T in terms of dynamic free volume, quantified by the Debye-Waller factor ⟨u^{2}⟩. Within this model, we show that the additive size alone controls the functional form of the T dependence. The LM parameters reach asymptotic values when the diluent size exceeds the monomer size, converging to a limit applicable to macroscopic interfaces.

Topics & Concepts

PolymerMaterials scienceRelaxation (psychology)DiluentThermodynamicsMonomerSensitivity (control systems)Chemical physicsLimit (mathematics)Dynamics (music)Statistical physicsPolymer blendMolecular dynamicsMolecular physicsMicrostructureCondensed matter physicsKineticsRheology and Fluid Dynamics StudiesMaterial Dynamics and PropertiesBlock Copolymer Self-Assembly
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