Enhanced Li capacity at high lithiation potentials in graphene oxide

We have studied lithiation of graphene oxide (GO) as a function of oxygen coverage using first principles calculations. Our results show that the lithiation potentials and capacities in GO can be tuned by controlling the oxygen coverage, or the degree of reduction. We find a range of coverages where the lithiation potentials are above the solid electrolyte interface (SEI) formation threshold, but with capacities comparable to, or larger than graphite. We observe that in highly oxidized and mildly reduced sheets, lithiation occurs through the formation of Li-O bonds, whereas at low coverages that are typical of reduced-GO (rGO) (O:C - 12.5 %), both Li-O bonds and LiC6 configurations are observed. The covalent Li-O bond is much stronger than the bonds formed in the LiC6 ring and the lithiation potentials for epoxides at high and medium coverages are generally large (> 1 eV). For these congifurations, as in the case of Li4Ti5O12 anodes, there will be no formation of SEI, but with the additional advantage of having higher lithium storage capacity than Li4Ti5O12. In reduced GO sheets, the presence of residual oxygen atoms allows for formation of covalent Li-O bonds that lead to storage capacities and lithiation potentials higher than that of graphite. Finally, our calculations show high lithiation potentials for the edges of graphene nanoribbons, which will impede the formation of SEI and hence lead to large reversible capacity.