Magnetically Responsive PDMS with aligned nickel coated carbon fibres

TL;DR

This paper presents a method to produce magnetically responsive PDMS actuators reinforced with nickel coated carbon fibres, allowing controlled anisotropic mechanical and magnetic properties for applications requiring fast, large strain responses.

Contribution

A novel fabrication technique for aligning nickel coated carbon fibres in PDMS using a low magnetic field, enabling tunable anisotropic properties and complex deformation behaviors.

Findings

Fibre orientation controls mechanical and magnetic responses.

Actuators achieve up to 60% strain with orientation-dependent behavior.

Large rotations beam model accurately predicts deformation.

Abstract

We detail a technique to produce actuators able to bear large strain and respond to an external magnetic field. The material used is PDMS reinforced with nickel coated carbon fibres. Thanks to the nickel functionalisation, the fibre orientation can be achieved by embedding the viscous solution into a low external magnetic field ($<0.2$~T). It is shown that both mechanical and magnetic properties can be controlled by tailoring the material anisotropy through properly orientating the reinforcing fibres in the pre-curing phase. The large strain behaviour is investigated by tensile testing up to 60 % of deformation and shows a strong dependence on the fibre orientation. The magnetic properties are investigated by placing beam-like specimens into a uniform magnetic field. The results show a multistable behaviour with a transition from a bending-only deformed configuration for the 0$^\circ$ fibres specimen, to a twisting only configuration, achieved for fibres at 90$^\circ$ whereas all the intermediate angles show both bending and twisting. This behaviour is accurately captured by the large rotations beam model introduced. Such an actuator can be used in all applications which require fast response times and large strain.