6533b856fe1ef96bd12b1c9b
RESEARCH PRODUCT
Mechanics of invagination and folding: Hybridized instabilities when one soft tissue grows on another
Tuomas TallinenJohn S. Bigginssubject
foldingMaterials scienceFOS: Physical sciencesModulusNanotechnologyPattern Formation and Solitons (nlin.PS)Chick EmbryoCondensed Matter - Soft Condensed MatterModels BiologicalInstabilityIntestinal mucosaAnimalsComputer SimulationPhysics - Biological PhysicsIntestinal MucosaCerebral Cortexsoft layered solidsta114Degenerate energy levelsFerretsNonlinear Sciences - Pattern Formation and SolitonsSupercritical fluidNonlinear systemfold morphologyNonlinear DynamicsZigzagBiological Physics (physics.bio-ph)Chemical physicsElastic substrateSoft Condensed Matter (cond-mat.soft)description
We address the folding induced by differential growth in soft layered solids via an elementary model that consists of a soft growing neo-Hookean elastic layer adhered to a deep elastic substrate. As the layer/substrate modulus ratio is varied from above unity towards zero we find a first transition from supercritical smooth folding followed by cusping of the valleys to direct subcritical cusped folding, then another to supercritical cusped folding. Beyond threshold the high amplitude fold spacing converges to about four layer thicknesses for many modulus ratios. In three dimensions the instability gives rise to a wide variety of morphologies, including almost degenerate zigzag and triple-junction patterns that can coexist when the layer and substrate are of comparable softness. Our study unifies these results providing understanding for the complex and diverse fold morphologies found in biology, including the zigzag precursors to intestinal villi, and disordered zigzags and triple-junctions in mammalian cortex.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2015-03-12 |