Boundary Curvature Effect on the Wrinkling of Thin Suspended Films

Abstract

In this letter, we demonstrate a relation between the boundary curvature and the wrinkle wavelength λ of a thin suspended film under boundary confinement. Experiments are done with nanocrystalline diamond films of thickness t ≈ 184~nm grown on glass substrates. By removing portions of the substrate after growth, suspended films with circular boundaries of radius R ranging from approximately 30 to 811 μm are made. Due to residual stresses, the portions of film attached to the substrate are of compressive prestrain ε0 ≈ 11 × 10-4 and the suspended portions of film are azimuthally wrinkled at their boundary. We find that λ monotonically decreases with and present a model predicting that λ t1/2(ε0 + R )-1/4, where R denotes a penetration depth over which strain relaxes at a boundary. This relation is in agreement with our experiments and may be adapted to other systems such as plant leaves. Also, we establish a novel method for measuring residual compressive strain in thin films.