Extracting Geometry and Topology of Orange Pericarps for the Design of Bioinspired Energy Absorbing Materials

As a result of evolution, many biological materials have developed irregular structures that lead to outstanding mechanical performances, like high stiffness-to-weight ratios and good energy absorption. However, reproducing these irregular biological structures in synthetic materials remains a complex design and fabrication challenge. Here, a bioinspired material design method is presented that characterizes the irregular structure as a network of building blocks, also known as tiles, and rules to connect them. Rather than replicating the biological structure one-to-one, synthetic materials are generated with the same distributions of tiles and connectivity rules as the biological material and it is shown that these equivalent materials have structure-to-property relationships similar to the biological ones. To demonstrate the method, the pericarp of the orange, a member of the citrus family known for its protective, energy-absorbing capabilities is studied. Polymer samples are generated and characterized under quasistatic and dynamic compression and display spatially-varying stiffness and good energy absorption, as seen in the biological materials. By quantifying which tiles and connectivity rules locally deform in response to loading, it is also determined how to spatially control the stiffness and energy absorption. A bioinspired material design method is presented to imitate the irregular structure of biological materials and obtain their outstanding mechanical properties. Rather than replicating the biological structure one-to-one, the method identifies distributions of fundamental building blocks and connectivity rules and generates synthetic equivalents with the same distributions. The method is demonstrated using the orange pericarp, known for protective, energy-absorbing capabilities. image