Employing density functional theory (DFT) calculations, we demonstrate that the stage-II configuration in de
lithiated LiFePO
4 is a thermodynamically metastable but kinetically controlled state, distinct from the thermodynamically favorable stages in graphite intercalation compounds (GICs). Based on the computational results, we propose a dual-interface model to describe the de
lithiation mechanism of LiFePO
4 upon charging. Accordingly, the experimentally observed LiFePO
4/stage-II/FePO
4 three-phase coexistence could be successfully reproduced. Formation of
lithium-staging configuration is mainly attributed to the Fe center mediated interlayer Li鈥揕i interactions, which is an essential indirect electrostatic force. The indirect interaction originates from the loca
lized nature of Fe 3
d electrons, for which the effective oxidation state of Fe redox is determined by the Li ion arrangement and, in turn, has an impact on the behavior of Li ion diffusion. Besides a better understanding of the microscopic
lithium diffusion mechanism in LiFePO
4, our results also shed
light on the interactions between electron and ion and further emphasize the importance of studying the Li diffusion kinetics at phase boundary in phase separation materials.
Keywords:
livine+LiFePO4&qsSearchArea=searchText">olivine LiFePO4; lithium+staging&qsSearchArea=searchText">lithium staging; lithium+ion+diffusion+kinetics&qsSearchArea=searchText">lithium ion diffusion kinetics; density functional theory calculations; Li ion batteries