Effects of strain stiffening and electrostriction on tunable elastic waves in compressible dielectric elastomer laminates

TL;DR

This study investigates how strain stiffening and electrostriction influence tunable elastic wave propagation in dielectric elastomer laminates, revealing how nonlinear effects and prestress can control wave band gaps for soft device applications.

Contribution

It introduces a nonlinear electromechanical model incorporating strain stiffening and electrostriction to analyze wave tunability in dielectric elastomer laminates, highlighting the role of snap-through instability.

Findings

Snap-through instability enables sharp wave band gap transitions.

Material properties and prestress significantly affect wave tunability.

Electrostrictive effects stabilize the dielectric elastomer laminate.

Abstract

This paper presents an electromechanical analysis of the nonlinear static response and the superimposed small-amplitude wave characteristics in an infinite periodic compressible dielectric elastomer (DE) laminate subjected to electrostatic excitations and prestress in the thickness direction. The enriched Gent material model is employed to account for the effects of strain stiffening and electrostriction of the DE laminate. The theory of nonlinear electroelasticity and related linearized incremental theory are exploited to derive the governing equations of nonlinear response and the dispersion relations of incremental shear and longitudinal waves. Numerical results reveal that the snap-through instability of a Gent DE laminate resulting from geometrical and material nonlinearities can be used to achieve a sharp transition in the position and width of wave band gaps. Furthermore, the influence of material properties (including Gent constants, the second strain invariant and electrostrictive parameters) and that of prestress on the snap-through instability and the electrostatic tunability of band gaps for both shear and longitudinal waves are discussed in detail. The electrostrictive effect and prestress are beneficial to stabilizing the periodic DE laminate. Depending on whether the snap-through instability occurs or not, a continuous variation or a sharp transition in wave band gaps can be realized by varying the electric stimuli. Our numerical findings are expected to provide a solid guidance for the design and manufacture of soft DE wave devices with tunable band structures.