Slippery and Wear Resistant Surfaces Enabled by Interface Engineered Graphene.

Friction and wear remain the primary cause of mechanical energy dissipation and system failure. Recent studies reveal graphene as a powerful solid lubricant to combat friction and wear. Most of these studies have focussed on nanoscale tribology and have been limited to a few specific surfaces. Here, we uncover many unknown aspects of graphene's contact-sliding at micro- and macroscopic tribo-scales over a broader range of surfaces. We discover that graphene's performance reduces for surfaces with increasing roughness. To overcome this, we introduce a new type of graphene/silicon nitride (SiNx, 3 nm) bilayer overcoats that exhibits superior performance compared to native graphene sheets ( mono and bi-layer) i.e. display the lowest microscale friction and wear on a range of tribologically poor flat surfaces. More importantly, 2 layer graphene/SiNx lubricant (< 4 nm in total thickness) shows the highest macroscale wear durability on tape-head (topologically variant surface) that exceeds even most of previous thicker (~7-100 nm) overcoats. Detailed nanoscale characterization and atomistic simulations explain the origin of the reduced friction and wear arising from these nanoscale coatings. Overall, this study demonstrates that engineered graphene-based coatings can outperform conventional coatings in a number of technologies.

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