Ling Li receives an NSF CAREER award to study the complex microstructures of biomaterials
Ling Li, an assistant professor of mechanical engineering in the College of Engineering, has received a National Science Foundation Faculty Early Career Development CAREER award to support research to study the structural designs and formation mechanisms of biomineralized architected materials.
The $520,000 five-year award will support Li’s research of the design and formation of biomineralized starfish skeletons.
“The internal microscopic structures of many biomineral-based structures found in organisms have extremely intricate 3D organizations,” Li said. “They show remarkable mechanical strength, durability, and efficiency, despite the fact that they are made of intrinsically brittle minerals and are often highly porous.”
Li’s research group focuses on the understanding the mechanical and multifunctional design of a variety of biological materials, such as low-density biological porous structures and tough biocomposites. His research also aims to develop new materials by utilizing the design strategies learned from biological material systems. For example, his group recently developed a chiton mollusk-inspired armor that provides simultaneous mechanical protection and flexibility.
“Currently, we have limited knowledge in explaining how biominerals’ complex 3D microstructures are controlled and how they are related to their mechanical properties. By using the biomineralized skeleton in a starfish as a model system, we aim to quantitatively characterize its 3D network-like microstructure, the underlying formation mechanisms as well as its mechanical significance,” he said.
Starfish skeletons contain hundreds of millimeter-sized mineralized elements known as ossicles, which are embedded within the soft body of the starfish. This skeletal design allows the starfish to be flexible in motion and stiff when required.
“Ossicles are characterized by their lattice-like porous microstructure, which is based on a single-crystalline calcite, which makes them lightweight, strong, and damage tolerant,” Li said. “The new knowledge gained from this study will provide us better understanding of the 3D structural evolution processes for echinoderms, or possibly even other invertebrate and vertebrate biomineralized tissues.”
Li said the work will provide lessons on the design and fabrication of synthetic low-density materials.
In addition to the CAREER Award, Li received the 2018 Air Force Office of Research Young Faculty Award, the 2019 MIT Technology Review TR35 China Award, and the 2019 College of Engineering Dean’s Award for Outstanding New Assistant Professor.
- Written by Rosaire Bushey