Improving electrochemical properties and structural stability of lithium manganese silicates as cathode materials for lithium ion batteries via introducing lithium excess

Abstract

The serious capacity decay caused by structural amorphization is still a major issue for polyanion-type lithium manganese silicates (Li2MnSiO4) as cathode material for lithium ion batteries. In this work, a new strategy for alleviating the structural instability via the introduction of excess lithium into the host crystal lattice is provided. A comprehensive study demonstrates that the required energy for the extraction/insertion of lithium ions into host crystal lattice was decreased as a result of changed local environment of cations in the compound after the excess lithium occupancy in lattice. Importantly, it was found that Li-rich samples deliver higher reversible capacity and increased average potential than pristine sample, indicating the improved energy density of polyanion-type Li2 + 2xMn1 − xSiO4/C. Additionally, the structure of Li2.2 sample was kept intact, while the Li2.0 sample was transformed to amorphous state at 200 mA h g−1 during the initial charging process by controlling the charge cut-off potential. As expected, the introduction of a certain amount of excess lithium into Li2MnSiO4 is explored as a route to achieving increased capacity with more movable lithium, while maintaining its structural stability and cyclic stability.