Wrinkling instability of 3D auxetic bilayers in tension

Bilayers (soft substrates coated with stiff films) are commonly found in nature with examples including skin tissue, vesicles, or organ membranes. They exhibit various types of instabilities when subjected to compression, depending on the contrast in material properties between the two components. We present wrinkling instabilities for 3D hyperelastic bilayer systems, including auxetics (materials with negative Poisson's ratio), under uni-axial tension. In tension, a soft bilayer can experience large lateral contraction, and we find that with an adequate contrast in the Poisson ratios, compressive stresses may develop and generate wrinkles aligned with the tensile direction. We rely on an analytic modelling of the phenomenon, and validate it with a user-defined Python script with periodic boundary conditions and constitutive relation implementation in advanced Finite Element simulations. Our findings reveal that wrinkles are observed when the Poisson ratio of the substrate is greater than that of the film. As the two Poisson ratios converge to a common value, the critical stretch of instability shoots up rapidly, and the wrinkling disappears. We also confirm these results by asymptotic analysis. This wrinkling analysis has significant potential in controlling surface patterns of auxetic skin grafts and hydrogel organ patches under mechanical loads. Moreover, the asymptotic expressions in this work can be used under finite strain for buckling-based metrology applications.