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Density functional theory and GGA-PW91 exchange correlation function were performed to simulate the bonding behavior of hydroxyl and epoxy groups on the graphene surface.We compared the different binding energies for two epoxy groups,as well as one hydroxyl group and one epoxy group on all possible positions within a 6-fold ring,respectively.The calculated results suggest that two oxygen-containing groups always tend to bind with the neighboring carbon atoms at the opposite sides.Moreover,two hydroxyl groups on the meta position are unstable,and one of the hydroxyl groups easily migrates to the para position.In contrast to the disperse arrangement,the aggregation of multiply hydroxyl groups largely enhances the binding energy of every hydroxyl group.It is worth noting that the binding sites and hydrogen bonds play an important role in stability.Our work further points out the number of oxygen-containing groups and the location of oxide region largely influence the electronic properties of graphene oxide.
Density functional theory and GGA-PW91 exchange correlation function were performed to simulate the bonding behavior of hydroxyl and epoxy groups on the graphene surface. We compared the different binding energies for two epoxy groups, as well as one hydroxyl group and one epoxy group on all possible positions within a 6-fold ring, respectively. The calculated results suggest that two oxygen-containing groups always tend to bind with the locally carbon atoms at the opposite sides. Moreover, two hydroxyl groups on the meta position are unstable, and one of the hydroxyl groups easily migrates to the para position. In contrast to the disperse arrangement, the aggregation of multiply hydroxyl groups substantially enhances the binding energy of every hydroxyl group. It is worth noting that the binding sites and hydrogen bonds play an important role in stability Our work further points out the number of oxygen-containing groups and the location of oxide region largely affect the electronic properties of graphene oxide.