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Superlubric polycrystalline graphene interfaces

Xiang Gao, Wengen Ouyang, Michael Urbakh, Oded Hod

2021Nature Communications47 citationsDOIOpen Access PDF

Abstract

The effects of corrugated grain boundaries on the frictional properties of extended planar graphitic contacts incorporating a polycrystalline surface are investigated via molecular dynamics simulations. The kinetic friction is found to be dominated by shear induced buckling and unbuckling of corrugated grain boundary dislocations, leading to a nonmonotonic behavior of the friction with normal load and temperature. The underlying mechanism involves two effects, where an increase of dislocation buckling probability competes with a decrease of the dissipated energy per buckling event. These effects are well captured by a phenomenological two-state model, that allows for characterizing the tribological properties of any large-scale polycrystalline layered interface, while circumventing the need for demanding atomistic simulations. The resulting negative differential friction coefficients obtained in the high-load regime can reduce the expected linear scaling of grain-boundary friction with surface area and restore structural superlubricity at increasing length-scales.

Topics & Concepts

Materials scienceGrain boundaryBucklingCrystalliteDislocationScalingMolecular dynamicsGraphenePlanarTribologyBoundary value problemMechanicsCondensed matter physicsComposite materialNanotechnologyGeometryPhysicsMicrostructureComputer scienceMetallurgyMathematicsQuantum mechanicsComputer graphics (images)Force Microscopy Techniques and ApplicationsMicrostructure and mechanical propertiesDiamond and Carbon-based Materials Research
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