Transition from confined to bulk dynamics in symmetric star-linear polymer mixtures
Daniele Parisi, Domenico Truzzolillo, Vishnu D. Deepak, Mario, Gauthier, Dimitris Vlassopoulos

TL;DR
This study investigates how the dynamics of linear polymers transition from confined to bulk behavior in symmetric star-linear polymer mixtures, revealing distinct scaling regimes and the influence of star compression.
Contribution
It demonstrates the decoupling of polymeric and colloidal responses in symmetric mixtures and identifies the crossover concentration for confined to bulk dynamics transition.
Findings
Two scaling regimes for plateau modulus and relaxation time.
Crossover concentration corresponds to maximum osmotic star compression.
Classical entangled polymer behavior recovered at high polymer concentrations.
Abstract
We report on the linear viscoelastic properties of mixtures comprising multiarm star (as model soft colloids) and long linear chain homopolymers in a good solvent. In contrast to earlier works, we investigated symmetric mixtures (with a size ratio of 1) and showed that the polymeric and colloidal responses can be decoupled. The adopted experimental protocol involved probing the linear chain dynamics in different star environments. To this end, we studied mixtures with different star mass fraction, which was kept constant while linear chains were added and their entanglement plateau modulus () and terminal relaxation time () were measured as functions of their concentration. Two distinct scaling regimes were observed for both and : at low linear polymer concentrations, a weak concentration dependence was observed, that became even weaker as the fraction of…
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