Litcius/Paper detail

Effect of microstructure evolution on the mechanical behavior of magneto-active elastomers with different matrix stiffness

Mehran Roghani, Dirk Romeis, Marina Saphiannikova

2023Soft Matter13 citationsDOIOpen Access PDF

Abstract

the local positions of the particles. In the case of initially isotropic MAEs made with a sufficiently soft matrix, this leads to the formation of chains of magnetized particles, creating a significant increase in the mechanical moduli along the field direction. In this paper, we implement a transversely isotropic Neo-Hookean material model to account for such anisotropic elastic behavior. A dipolar mean field approach is used to describe magnetic interactions between the particles. A penalty term is introduced to compensate for the micro-mechanical elastic energy required to move the particles inside the cross-linked elastomer. The resulting model can predict the huge magneto-rheological effects observed in experiments, and improves our understanding of how microstructure evolution affects magnetically induced deformation and stiffness of MAEs.

Topics & Concepts

ElastomerMicrostructureMaterials scienceStiffnessMagnetoComposite materialMatrix (chemical analysis)Mechanical engineeringMagnetEngineeringAdvanced Materials and MechanicsVibration Control and Rheological FluidsCharacterization and Applications of Magnetic Nanoparticles