Surface elasticity effect on Plateau-Rayleigh instability in soft solids

TL;DR

This study investigates how surface elasticity influences the Plateau-Rayleigh instability in soft solids, combining theoretical modeling and numerical simulations to understand the effects of surface parameters on instability behavior.

Contribution

The paper introduces a coupled 1D and 3D modeling approach to analyze surface elasticity effects on PR instability in soft solids, filling a gap in prior research.

Findings

Surface elasticity significantly affects the onset and evolution of PR instability.

The developed models accurately predict instability behavior under various surface conditions.

Insights can be used to calibrate surface parameters and improve material models.

Abstract

Soft solids exhibit instability and develop surface undulations due to surface effects, a phenomenon known as the elastic Plateau-Rayleigh (PR) instability, driven by the interplay of surface and bulk elasticity. Previous studies on the PR instability in solids mainly focused on the case of constant surface tension and ignored the effect of surface elasticity. It has been shown by experiments that the surface effects in solid-like materials depend both on the surface tension and surface elasticity, but little is known about the role of the latter in the elasto-capillary instabilities in soft solids. Here, we conduct an in-depth exploration of the effect of surface elasticity on the PR instability in an elastic cylinder by coupling theoretical and numerical methods. We derive an asymptotically consistent one-dimensional (1d) model to characterize the PR instability from three-dimensional (3d) nonlinear bulk-surface elasticity, and develop a new finite-element (FE) scheme for simulating 3d deformations of the bulk-surface system. The initiation and evolution of the PR instability are obtained analytically with the aid of the 1d model. The 1d results are further validated by the 3d FE simulations. By synthesizing the 1d analytic solutions and 3d numerical results, the effects of surface elasticity, surface compressibility, surface tension, axial force and geometrical size on the PR instability are thoroughly elucidated. Our results can be applied to calibrate surface parameters for solid-like materials and develop constitutive models for elastic surfaces.