A Kirchhoff-like theory for hard magnetic rods under geometrically nonlinear deformation in three dimensions

TL;DR

This paper develops a Kirchhoff-like 1D theory for hard magnetic rods undergoing large 3D deformations, validated by experiments and simulations, advancing the understanding of magneto-elastic behavior in slender structures.

Contribution

It introduces a new effective 1D nonlinear theory for hard magnetic rods derived from 3D energy, extending previous planar models to full 3D deformations.

Findings

The theory accurately predicts 3D deformation behaviors.

Experimental results confirm the model's validity.

Limitations include neglecting long-range dipole interactions.

Abstract

Magneto-rheological elastomers (MREs) are functional materials that can be actuated by applying an external magnetic field. MREs comprise a composite of hard magnetic particles dispersed into a nonmagnetic elastomeric matrix. By applying a strong magnetic field, one can magnetize the structure to program its deformation under the subsequent application of an external field. Hard MREs, whose coercivities are large, have been receiving particular attention because the programmed magnetization remains unchanged upon actuation. Hence, once a structure made of a hard MRE is magnetized, it can be regarded as magnetized permanently. Motivated by a new realm of applications, there have been significant theoretical developments in the continuum description of hard MREs. By reducing the 3D description into 1D or 2D via dimensional reduction, several theories of hard magnetic slender structures such as linear beams, elastica, and shells have been recently proposed. In this paper, we derive an effective theory for MRE rods under geometrically nonlinear 3D deformation. Our theory is based on reducing the 3D magneto-elastic energy functional for the hard MREs into a 1D Kirchhoff-like description. Restricting the theory to 2D, we reproduce previous works on planar deformations. For further validation in the general case of 3D deformation, we perform precision experiments with both naturally straight and curved rods under either constant or constant-gradient magnetic fields. Our theoretical predictions are in excellent agreement with both discrete simulations and precision-model experiments. Finally, we discuss some limitations of our framework, as highlighted by the experiments, where long-range dipole interactions, which are neglected in the theory, can play a role.