Macro-superlubricity in sputtered MoS2-based films by decreasing edge pinning effect

To date, MoS2 can only be achieved at microscale. Edge pinning effect caused by structure defects is the most obvious barrier to expand the size of structural superlubricity to macroscale. Herein, we plan to pin edge planes of MoS2 with nanospheres, and then the incommensurate structure can be formed between adjacent rolling nanoparticles to reduce friction. The sputtered MoS2 film was prepared by the physical vapor deposition (PVD) in advance. Then enough Cu2O nanospheres (similar to 40 nm) were generated in situ at the edge plane of MoS2 layers by liquid phase synthesis. An incommensurate structure (mismatch angle (theta) = 8 degrees) caused by MoS2 layers was formed before friction. The friction coefficient of the films (5 N, 1,000 r/min) was similar to 6.0x10(-3) at the most. During friction, MoS2 layers pinned on numerous of Cu2O nanoparticles reduced its edge pinning effect and decreased friction. Moreover, much more incommensurate was formed, developing macro-superlubricity.

Automated summary

By pinning the edge planes of MoS2 with nanospheres, an incommensurate structure is formed between adjacent rolling nanoparticles, reducing friction and achieving macro-superlubricity.