Magnetorheological elastomers (MREs) are a class of recently emerged smart materials
whose moduli are largely influenced when exposed to an external magnetic field. The MREs …

Since the beginning of the industrial age, material performance and design have been in the
midst of innovation of many disruptive technologies. Today's electronics, space, medical …

Recent advances in magnetorheological elastomers (MREs) have posed the question on
whether the combination of both soft-and hard-magnetic particles may open new routes to …

The objective of this contribution is to present a unifying review on strain-driven
computational homogenization at finite strains, thereby elaborating on computational …

Material modeling using modern numerical methods accelerates the design process and
reduces the costs of developing new products. However, for multiscale modeling of …

This article focuses on computational multiscale methods for the mechanical response of
nonlinear heterogeneous materials. After a short historical note, a brief overview is given of …

Composite materials and structures are inherently inhomogeneous and anisotropic across
multiple scales. Multiscale modelling offers opportunities to understand the coupling of …

This work deals with a comprehensive theoretical and numerical framework that allows the
modeling of finite strain magnetorheological elastomers (MREs) comprising mechanically …

We present a framework for the multiscale modeling of finite strain magneto-elasticity based
on physics-augmented neural networks (NNs). By using a set of problem specific invariants …

This article is a review of models that capture the magneto-mechanical response of
magnetorheological elastomers (MREs) and MRE-based systems. Where available …