Abstract
Understanding the mechanism of slow lithium ion (Li(+)) transport kinetics in LiFePO(4) is not only practically important for high power density batteries but also fundamentally significant as a prototypical ion-coupled electron transfer process. Substantial evidence has shown that the slow ion transport kinetics originates from the coupled transfer between electrons and ions and the phase segregation of Li(+). Combining a model Hamiltonian analysis and DFT calculations, we reveal that electrostatic interactions play a decisive role in coupled charge transfer and Li(+) segregation. The obtained potential energy surfaces prove that ion-electron coupled transfer is the optimal reaction pathway due to electrostatic attractions between Li(+) and e(-) (Fe(2+)), while prohibitively large energy barriers are required for separate electron tunneling or ion hopping to overcome the electrostatic energy between the Li(+)-e(-) (Fe(2+)) pair. The model reveals that Li(+)-Li(+) repulsive interaction in the [010] transport channels together with Li(+)-e(-) (Fe(2+))-Li(+) attractive interaction along the [100] direction cause the phase segregation of Li(+). It explains why the thermodynamically stable phase interface between Li-rich and Li-poor phases in LiFePO(4) is perpendicular to [010] channels.