Physics – Fluid Dynamics
Scientific paper
2011-08-18
Physics
Fluid Dynamics
17 pages, 6 figures. Submited to Physical Review E on 13Jun11
Scientific paper
10.1103/PhysRevE.84.056329
Using equilibrium and non-equilibrium molecular dynamic (MD) simulations, we found that engineering the strain on the graphene planes forming a channel can drastically change the interfacial friction of water transport through it. There is a sixfold change of interfacial friction stress when the strain changes from -10% to 10%. Stretching the graphene walls increases the interfacial shear stress, while compressing the graphene walls reduces it. Detailed analysis of the molecular structure reveals the essential roles of the interfacial potential energy barrier and the structural commensurateness between the solid walls and the first water layer. Our results suggest that the strain engineering is an effective way of controlling the water transport inside nano-channels. The resulting quantitative relations between shear stress and slip velocity and the understanding of the molecular mechanisms will be invaluable in designing graphene nano-channel devices.
Liu Jefferson Zhe
Ma Ming
Sheridan John
Xiong Wei
Xu Zhiping
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