Issue 10, 2016

Complete wetting of graphene by biological lipids

Abstract

Graphene nanosheets have been demonstrated to extract large amounts of lipid molecules directly out of the cell membrane of bacteria and thus cause serious damage to the cell's integrity. This interesting phenomenon, however, is so far not well understood theoretically. Here through extensive molecular dynamics simulations and theoretical analyses, we show that this phenomenon can be categorized as a complete wetting of graphene by membrane lipids in water. A wetting-based theory was utilized to associate the free energy change during the microscopic extraction of a lipid with the spreading parameter for the macroscopic wetting. With a customized thermodynamic cycle for detailed energetics, we show that the dispersive adhesion between graphene and lipids plays a dominant role during this extraction as manifested by the curved graphene. Our simulation results suggest that biological lipids can completely wet the concave, flat or even convex (with a small curvature) surface of a graphene sheet.

Graphical abstract: Complete wetting of graphene by biological lipids

Supplementary files

Article information

Article type
Paper
Submitted
08 Jan 2016
Accepted
06 Feb 2016
First published
08 Feb 2016

Nanoscale, 2016,8, 5750-5754

Complete wetting of graphene by biological lipids

B. Luan, T. Huynh and R. Zhou, Nanoscale, 2016, 8, 5750 DOI: 10.1039/C6NR00202A

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