Two-Dimensional Stacked Composites of Self-Assembled Alkane Layers and Graphene for Transparent Gas Barrier Films with Low Permeability

Self-assembled alkane layers are introduced between graphene layers to physically block nanometer size defects in graphene and lateral gas pathways between graphene layers. A well-defined hexatriacontane (HTC) monolayer on graphene could cover nanometer-size defects because of the flexible nature and strong intermolecular van der Waals interactions of alkane, despite the roughness of graphene. In addition, HTC multilayers between graphene layers greatly improve their adhesion. This indicates that HTC multilayers between graphene layers can effectively block the lateral pathway between graphene layers by filling open space with close-packed self-assembled alkanes. By these mechanisms, alternately stacked composites of graphene and self-assembled alkane layers greatly increase the gas-barrier property to a water vapor transmission rate (WVTR) as low as 1.2 x 10(-3) g/(m(2) day), whereas stacked graphene layers generally show a WVTR < 0.5 g/ (m(2) day). Furthermore, the self-assembled alkane layers have superior crystallinity and wide bandgap, so they have little effect on the transmittance.

Automated summary

By introducing self-assembled alkane layers between graphene layers, nanometer size defects in graphene and lateral gas pathways can be effectively blocked. The flexible nature and strong intermolecular interactions of alkane allow it to cover defects and improve the adhesion of graphene layers. This stacked structure greatly enhances the gas-barrier property without affecting the transmittance.