On the effective magnetostrictive properties of anisotropic magneto-active elastomers in the small-deformation limit

Abstract: Magneto-active elastomers (MAEs) are composite materials comprising an elastomer matrix with embedded magnetic particles, endowing the composite with coupled effective magneto-mechanical responses. It is widely reported that anisotropic MAEs exhibit much stronger magneto-mechanical coupling than isotropic MAEs. However, most efforts to model effective magneto-mechanical properties of MAEs via homogenization focused on isotropic microstructures or those with large separations between particles, to use analytical solutions. In this work, we introduce a periodic homogenization approach to compute effective magneto-mechanical properties of anisotropic MAEs, and analyze microstructural features that enhance the magneto-mechanical coupling. Using the finite element method, we numerically determine the effect of particle shape, gap, and voids on the effective stiffness, permeability, and magneto-mechanical coupling tensors for chain-like periodic microstructures. Using insights gained from the full-field simulations, we derive an analytical expression for the magneto-mechanical coupling in the chain direction, in terms of the volume fraction, gap size, and properties of the matrix and particles. Results show that the overall magnetostriction of anisotropic MAEs is most sensitive to the gap between particles and the waviness of the particle chains, with smaller gap sizes and straighter chains yielding higher overall magnetostriction. Simulations also show that while isotropic MAEs elongate in a uniform magnetic field, anisotropic MAEs contract with much larger strain amplitudes, a result of the attractive forces between particles being much stronger in anisotropic MAEs than in isotropic MAEs. Results provide fundamental insights into the mechanisms that govern magneto-mechanical coupling in anisotropic MAEs, and constitute a toolbox of homogenized MAE material properties.