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Local Mechanism Governs Global Reinforcement of Nanofiller-Hydrogel Composites

Ippolyti Dellatolas, Minaspi Bantawa, Brian Damerau, Ming Guo, Thibaut Divoux, Emanuela Del Gado, Irmgard Bischofberger

2023ACS Nano73 citationsDOI

Abstract

We reveal the mechanism for the strong reinforcement of attractive nanofiller-hydrogel composites. Measuring the linear viscoelastic properties of hydrogels containing filler nanoparticles, we show that a significant increase of the modulus can be achieved at unexpectedly low volume fractions of nanofillers when the filler-hydrogel interactions are attractive. Using three-dimensional numerical simulations, we identify a general microscopic mechanism for the reinforcement, common to hydrogel matrices of different compositions and concentrations and containing nanofillers of varying sizes. The attractive interactions induce a local increase in the gel density around the nanofillers. The effective fillers, composed of the nanofillers and the densified regions around them, assemble into a percolated network, which constrains the gel displacement and enhances the stress coupling throughout the system. A global reinforcement of the composite is induced as the stresses become strongly coupled. This physical mechanism of reinforcement, which relies only on attractive filler-matrix interactions, provides design strategies for versatile composites that combine low nanofiller fractions with an enhanced mechanical strength.

Topics & Concepts

Materials scienceComposite materialReinforcementViscoelasticityComposite numberSelf-healing hydrogelsNanocompositeModulusFiller (materials)NanoparticleElastic modulusVolume fractionNanotechnologyPolymer chemistryHydrogels: synthesis, properties, applicationsAdvanced Materials and MechanicsPolymer Surface Interaction Studies
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