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Real-Time Quantification of Molecular-Level Dynamic Behaviors Underpinning Shear Thinning in End-Linked Associative Polymer Networks

Yu Zheng, Devosmita Sen, Weizhong Zou, Kexin Dai, Bradley D. Olsen

2024Journal of the American Chemical Society8 citationsDOI

Abstract

Shear thinning of associative polymers is tied to bond breakage under deformation and retraction of dangling chains, as predicted by transient network theories. However, an in-depth understanding of the molecular mechanisms is limited by our ability to measure the molecular states of the polymers during deformation. Herein, utilizing a custom-built rheo-fluorescence setup, bond dissociation in model end-linked associative polymers is quantified in real time with nonlinear shear deformation based on a fluorescence quench transition when phenanthroline ligands bind with Ni 2+ . All of the networks exhibit shear thinning, and the dangling chain fraction increases with the shear rate. However, the number of broken bonds is smaller than that predicted by transient network theories, indicating additional relaxation modes or topological inhomogeneities in the networks. Through tuning counteranion chemistry, networks with similar relaxation times but varying dissociation and association rate constants ( k d and k a ) of Ni 2+ -phenanthroline cross-links are developed. Decreasing k a contributes to more dangling chain formation, while the effect of k d is less pronounced. Following force-accelerated bond dissociation of bridging chains, the dangling ends in networks with higher k a tend to reassociate to form elastically inactive loops, while the dangling chains are preserved in networks with lower k a . This indicates the critical role of bond reassociation kinetics in dictating shear-induced topological interchange of different chain configurations. Besides reaction kinetics, decreasing network junction functionality results in less shear thinning and broken bonds, originating from the lower amount of bond breakage required to flow and the higher tendency of the dissociated bonds to reform bridging chains.

Topics & Concepts

ChemistryUnderpinningShear thinningThinningRheologyThermodynamicsEcologyGeotechnical engineeringGeologyBiologyPhysicsAdvanced Polymer Synthesis and CharacterizationPolymer composites and self-healingDendrimers and Hyperbranched Polymers