Abstract
Two-dimensional (2D) layered nanomaterials such as graphene, molybdenum disulfide (MoS2), or tungsten disulfide offer a promising solution in areas of solid-state lubrication, due to their excellent mechanical properties as well as low friction. However, defects can influence their friction and reduce their superior tribological properties. Thus, it is crucial to understand the effects of defects on sliding behavior in 2D nanomaterials, to foster a functional strategy for utilizing 2D nanomaterials as solid-state tribological films. In this study, frictional effects of defects, grain boundaries, and atomic-scale structural defects were explored on chemical vapor deposition (CVD) grown single layer MoS2. Selective patterning of defects into MoS2 was accomplished via controlled irradiation of helium ions with varying ion doses. The friction of MoS2 was characterized by friction force microscopy (FFM) and was found that friction depends on the defect formation controlled by helium ion irradiation. This approach offers a correlation between surface topography, defects and friction. Understanding the relative friction of MoS2 in the presence of different levels of defects is foundational to studying tribological properties of a single layer MoS2 at both nanoscales and macroscales.
