Tunable macroscale structural superlubricity in two-layer graphene via strain engineering

Achieving structural superlubricity in graphitic samples of macro-scale size is particularly challenging due to difficulties in sliding large contact areas of commensurate stacking domains. Here, we show the presence of macro-scale structural superlubricity between two randomly stacked graphene laye...

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Bibliographic Details
Published in:arXiv.org 2020-04
Main Authors: Androulidakis, Charalampos, Koukaras, Emmanuel N, Paterakis, George, Trakakis, George, Galiotis, Costas
Format: Article
Language:English
Subjects:
Graphene
Interlayers
Lattice parameters
Molecular dynamics
Shear stress
Shearing
Stacking
Tensile strain
Online Access:Get full text
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Summary:Achieving structural superlubricity in graphitic samples of macro-scale size is particularly challenging due to difficulties in sliding large contact areas of commensurate stacking domains. Here, we show the presence of macro-scale structural superlubricity between two randomly stacked graphene layers produced by both mechanical exfoliation and CVD. By measuring the shifts of Raman peaks under strain we estimate the values of frictional interlayer shear stress (ILSS) in the superlubricity regime (mm scale) under ambient conditions. The random incommensurate stacking, the presence of wrinkles and the mismatch in the lattice constant between two graphene layers induced by the tensile strain differential are considered responsible for the facile shearing at the macroscale. Furthermore, molecular dynamic simulations show that the stick-slip behaviour does not hold for achiral shearing directions for which the ILSS decreases substantially, supporting the experimental observations. Our results pave the way for overcoming several limitations in achieving macroscale superlubricity in graphene.
ISSN:2331-8422
DOI:10.48550/arxiv.2004.01936