Size and charge effects on the structural stability of LiMO₂ (M = transition metal) compounds

Abstract

The stuctural stability of ordered rocksalt structures with composition AMO₂ (A =alkali metal; M =transition metal) is investigated as a function of size and charge of the cations. Many of these materials are of interest for their applications as intercalation electrodes in rechargeable batteries. The ionic size and charge of the A and M cations are controlled by varying the cation-oxygen interaction parameters of a Buckinghani interaction potential. Our calculations show that the α-LiFeO₂ structure is stabilized for A and M cations of approximately the same size because of a favourable electrostatic energy. As size differences between the cations are increased, the layered α-NaFeO structure is stabilized. The LiMnO₂ and low-temperature LiCoO₂ structures are found to be stable only in a narrow region of parameter space. These calculations also show that as the charge on the M cation is reduced, the α-NaFeO₂ structure is stabilized for a wider range of cation sizes. We compare the results of our calculations with experimental data.