Planar structured materials with extreme elastic anisotropy

Designing anisotropic structured materials by reducing symmetry results in unique behaviors, such as shearing under uniaxial compression or tension. This direction-dependent coupled mechanical phenomenon is crucial for applications such as energy redirection. While rank-deficient materials such as hierarchical laminates have been shown to exhibit extreme elastic anisotropy, there is limited knowledge about the fully anisotropic elasticity tensors achievable with single-scale fabrication techniques. No established upper and lower bounds on anisotropic moduli achieving extreme elastic anisotropy exist, similar to Hashin-Shtrikman bounds in isotropic composites. In this paper, we estimate the range of anisotropic stiffness tensors achieved by single-scale two-dimensional structured materials. To achieve this, we first develop a database of periodic anisotropic single-scale unit cell geometries using linear combinations of periodic cosine functions. The database covers a wide range of anisotropic elasticity tensors, which are then compared with the elasticity tensors of hierarchical laminates. Through this comparison, we identify the regions in the property space where hierarchical design is necessary to achieve extremal properties. We demonstrate a method to construct various 2D functionally graded structures using this cosine function representation for the unit cells. These graded structures seamlessly interpolate between unit cells with distinct patterns, allowing for independent control of several functional gradients, such as porosity, anisotropic moduli, and symmetry. The graded structures exhibit unique mechanical behaviors when designed with unit cells positioned at extreme parts of the property space. Specific graded designs are numerically studied to observe behaviors such as selective strain energy localization, compressive strains under tension, and localized rotations.