Axisymmetric necking of a circular electrodes-coated dielectric membrane

TL;DR

This paper investigates a new localized axisymmetric necking instability in electrodes-coated dielectric membranes under electric and tension forces, which may occur before traditional instabilities and impact dielectric elastomer actuator integrity.

Contribution

It derives the bifurcation condition for axisymmetric necking and demonstrates its occurrence prior to other known instabilities, providing new insights into membrane failure mechanisms.

Findings

Necking can occur before limiting point and Treloar-Kearsley instabilities.

A nonlinear amplitude equation describes the near-critical behavior.

Localized solutions bifurcate from homogeneous states, indicating a three-stage necking process.

Abstract

We investigate the stability of a circular electrodes-coated dielectric membrane under the combined action of an electric field and all-round in-plane tension. It is known that such a membrane is susceptible to the limiting point instability (also known as pull-in instability) which is widely believed to be a precursor to electric breakdown. However, there is experimental evidence showing that the limiting point instability may not necessarily be responsible for rapid thinning and electric breakdown. We explore the possibility that the latter is due to a new instability mechanism, namely localised axisymmetric necking. The bifurcation condition for axisymmetric necking is first derived and used to show that this instability may occur before the Treloar-Kearsley instability or the limiting point instability for a class of free energy functions. A weakly nonlinear analysis is then conducted and it is shown that the near-critical behavior is described by a fourth order nonlinear ODE with variable coefficients. This amplitude equation is solved using the finite difference method and it is demonstrated that a localised solution does indeed bifurcate from the homogeneous solution. Based on this analysis and what is already known for the purely mechanical case, we may deduce that the necking evolution follows the same three stages of initiation, growth and propagation as other similar localisation problems. The insight provided by the current study is expected to be relevant in assessing the integrity of dielectric elastomer actuators.