@article{Lei2026, 
author = {Lei Lei and Qian Cao and Yuchi Wu and Mintang Liu and Jing Zheng and Yuanyuan Mei and Zhongrong Zhou},
title = {Bioinspired ceramic scaffold-reinforced PTFE composites achieving near-zero wear and self-lubrication under extreme conditions},
year = {2026},
journal = {Friction},
volume = {14},
number = {2},
pages = {9441110},
keywords = {wear resistance, self-lubrication, biomimetic design, extreme conditions, cellular-structured ceramic scaffold, polytetrafluoroethylene (PTFE) composites},
url = {https://www.sciopen.com/article/10.26599/FRICT.2025.9441110},
doi = {10.26599/FRICT.2025.9441110},
abstract = {The development of high-performance polytetrafluoroethylene (PTFE) composites with excellent wear resistance and self-lubrication under heavy-load and high-speed conditions is urgently needed for advanced tribological applications in many fields, including aviation and aerospace, but this development remains a challenge. Human enamel, a natural composite capable of enduring millions of chewing cycles under pressures up to ~2.5 GPa, serves as an ideal model for advanced wear-resistant composites. Herein, a biomimetic design strategy inspired by the antiwear effect of the enamel rod/interrod structure is proposed to create PTFE composites with a cell-structured ceramic scaffold reinforcement microstructure. By utilizing the preferential load support effect and debris size control mechanism of ceramic scaffolds, bioinspired composites achieve excellent wear resistance with effective self-lubrication. Furthermore, a polydopamine (PDA) modification technology for PTFE components is employed to increase the adhesion and stability of PTFE transfer films, thereby improving the self-lubrication performance of the composites. Consequently, the resulting composites exhibit outstanding tribological properties, especially those characterized by near-zero wear and good self-lubricity under heavy loads and high speeds. This work will advance the development of high-performance self-lubricating composites suitable for extreme conditions. Furthermore, the proposed design strategy is expected to be applicable to other biological prototypes, enabling the creation of diverse high-performance functional composites.}
}