Litcius/Paper detail

Surface Instability in a Nematic Elastomer

Morgan Barnes, Fan Feng, John S. Biggins

2023Physical Review Letters16 citationsDOIOpen Access PDF

Abstract

Liquid crystal elastomers (LCEs) are soft phase-changing solids that exhibit large reversible contractions upon heating, Goldstone-like soft modes, and resultant microstructural instabilities. We heat a planar LCE slab to isotropic, clamp the lower surface, then cool back to nematic. Clamping prevents macroscopic elongation, producing compression and microstructure. We see that the free surface destabilizes, adopting topography with amplitude and wavelength similar to thickness. To understand the instability, we numerically compute the microstructural relaxation of a "nonideal" LCE energy. Linear stability reveals a Biot-like scale-free instability, but with oblique wave vector. However, simulation and experiment show that, unlike classic elastic creasing, instability culminates in a crosshatch without cusps or hysteresis, and is constructed entirely from low-stress soft modes.

Topics & Concepts

InstabilityMaterials scienceLiquid crystalCondensed matter physicsIsotropyAmplitudePlanarSurface energyOpticsElastomerMesoscopic physicsPhase (matter)Relaxation (psychology)MechanicsPhysicsComposite materialPsychologySocial psychologyComputer scienceQuantum mechanicsComputer graphics (images)Advanced Materials and MechanicsLiquid Crystal Research AdvancementsStructural Analysis and Optimization
Surface Instability in a Nematic Elastomer | Litcius