Tunable dynamic moduli of magnetic elastomers: from X-$\mu$CT characterization to mesoscopic modeling

TL;DR

This paper combines experimental X-ray micro-CT data with mesoscopic modeling to study how magnetic elastomers' mechanical properties change under magnetic fields, revealing complex static and dynamic moduli behavior.

Contribution

It introduces a coarse-grained dipole-spring model based on real micro-CT data to analyze magnetostriction and elastic moduli in magnetic elastomers.

Findings

Magnetic particles form chain-like aggregates with increasing magnetization.

Static elastic moduli initially decrease then increase with magnetic interactions.

Dynamic moduli exhibit nonmonotonic behavior depending on frequency and magnetization.

Abstract

Ferrogels and magnetoelastomers are composite materials obtained by embedding magnetic particles of mesoscopic size in a crosslinked polymeric matrix. They combine the reversible elastic deformability of polymeric materials with the high responsivity of ferrofluids to external magnetic fields. These materials stand out, for example, for large magnetostriction as well as significant increase of the elastic moduli in the presence of external magnetic fields. By means of X-ray micro-computed tomography, position and size of each magnetic particle can be measured with a high degree of accuracy. We here use data extracted from real magnetoelastic samples as input for coarse-grained dipole-spring modeling and calculations to investigate magnetostriction, stiffening, and changes in the normal modes spectrum. More precisely, we assign to each particle a dipole moment proportional to its volume and set a randomized network of springs between them that mimics the behavior of the polymeric elastic matrix. Extending our previously developed methods, we compute the resulting structural changes in the systems, their overall distortions, as well as the frequency-dependent elastic moduli when magnetic interactions are turned on. Particularly, with increasing magnetization, we observe the formation of chain-like aggregates, resulting in significant overall deformations. Interestingly, the static elastic moduli can first show a slight decrease with growing amplitude of the magnetic interactions, before a pronounced increase appears upon the chain formation. The change of the dynamic moduli with increasing magnetization depends on the frequency and can even show nonmonotonic behavior. Overall, we demonstrate how theory and experiments can complement each other to learn more about the dynamic behavior of this interesting class of materials.