6533b82efe1ef96bd12932c0

RESEARCH PRODUCT

Surface sulci in squeezed soft solids

John S. BigginsTuomas TallinenTuomas TallinenLakshminarayanan Mahadevan

subject

Surface (mathematics)Materials sciencemekaniikkata114Condensed matter physicsbusiness.industryPhysicsIsotropyFluid Dynamics (physics.flu-dyn)General Physics and AstronomyFOS: Physical sciencesPhysics - Fluid DynamicsCondensed Matter - Soft Condensed MatterCritical valueMechanicsInstabilityStress (mechanics)OpticsBucklingPhase (matter)CompressibilitySoft Condensed Matter (cond-mat.soft)fysiikkabusiness

description

The squeezing of soft solids, the constrained growth of biological tissues, and the swelling of soft elastic solids such as gels can generate large compressive stresses at their surfaces. This causes the otherwise smooth surface of such a solid to become unstable when its stress exceeds a critical value. Previous analyses of the surface instability have assumed two-dimensional plane-strain conditions, but in experiments isotropic stresses often lead to complex three-dimensional sulcification patterns. Here we show how such diverse morphologies arise by numerically modeling the lateral compression of a rigidly clamped elastic layer. For incompressible solids, close to the instability threshold, sulci appear as $\mathsf{I}$-shaped lines aligned orthogonally with their neighbors; at higher compressions they are $\mathsf{Y}$-shaped and prefer a hexagonal arrangement. In contrast, highly compressible solids when squeezed show only one sulcified phase characterized by a hexagonal sulcus network.

yearjournalcountryeditionlanguage
2013-01-01
https://dx.doi.org/10.48550/arxiv.1405.7296