Structural Orientation and Anisotropy in Biological Materials: Functional Designs and Mechanics
Abstract
Biological materials exhibit anisotropic characteristics because of the anisometric nature of their constituents and their preferred alignment within interfacial matrices. The regulation of structural orientations is the basis for material designs in nature and may offer inspiration for man‐made materials. Here, how structural orientation and anisotropy are designed into biological materials to achieve diverse functionalities is revisited. The orientation dependencies of differing mechanical properties are introduced based on a 2D composite model with wood and bone as examples; as such, anisotropic architectures and their roles in property optimization in biological systems are elucidated. Biological structural orientations are designed to achieve extrinsic toughening via complicated cracking paths, robust and releasable adhesion from anisotropic contact, programmable dynamic response by controlled expansion, enhanced contact damage resistance from varying orientations, and simultaneous optimization of multiple properties by adaptive structural reorientation. The underlying mechanics and material‐design principles that could be reproduced in man‐made systems are highlighted. Finally, the potential and challenges in developing a better understanding to implement such natural designs of structural orientation and anisotropy are discussed in light of current advances. The translation of these biological design principles can promote the creation of new synthetic materials with unprecedented properties and functionalities.
Document Details
- Document Type
- Pub Defense Publication
- Publication Date
- Jan 03, 2020
- Source ID
- 10.1002/adfm.201908121
Entities
People
- Robert O. Ritchie
- Zengqian Liu
- Zhefeng Zhang
Organizations
- Air Force Office of Scientific Research
- National Natural Science Foundation of China
- School of Materials, University of Manchester
- University of California, Berkeley