Wrinkling of a bilayer membrane
arXiv:cond-mat/0611507 · doi:10.1103/PhysRevE.75.016609
Abstract
The buckling of elastic bodies is a common phenomenon in the mechanics of solids. Wrinkling of membranes can often be interpreted as buckling under constraints that prohibit large amplitude deformation. We present a combination of analytic calculations, experiments, and simulations to understand wrinkling patterns generated in a bilayer membrane. The model membrane is composed of a flexible spherical shell that is under tension and that is circumscribed by a stiff, essentially incompressible strip with bending modulus B. When the tension is reduced sufficiently to a value Ï, the strip forms wrinkles with a uniform wavelength found theoretically and experimentally to be λ= 2Ï(B/Ï)^{1/3}. Defects in this pattern appear for rapid changes in tension. Comparison between experiment and simulation further shows that, with larger reduction of tension, a second generation of wrinkles with longer wavelength appears only when B is sufficiently small.
9 pages, 5 color figures