01916nas a2200181   4500000000100000008004100001260003000042100001800072700002200090700001900112700001800131245013800149856004500287300001400332490000800346520136600354020001401720       2015                            d  bAmerican Chemical Society1 aTanmay Sarkar1 aMridula Bharadwaj1 aUmesh Waghmare1 aParveen Kumar00aMechanism of Charge Transfer in Olivine-Type LiFeSiO4 and LiFe0.5M0.5SiO4 (M = Mg or Al) Cathode Materials: First-Principles Analysis  uhttps://doi.org/10.1021/acs.jpcc.5b01692  a9125-91330 v1193 aOlivine silicates LiMSiO4 (where M = Mn, Fe, Co, and Ni) are promising candidates for the next generation of cathode materials for use in lithium ion batteries (LIB). Among these compounds, LiFeSiO4 is an attractive choice due to its low cost, environmental friendliness, high safety, and stability. In this work, we use first-principles density functional theory-based calculations to determine the structural and electrochemical properties of olivine-type LiFeSiO4 and LiFe0.5M0.5SiO4 (where M = Mg or Al). Because of the influence of stronger Si–O bonds in weakening Fe–O bonds via an inductive effect, we find that these compounds have a high lithium intercalation voltage (i.e., ∼ 5 V) and undergo negligible changes in volume during lithiation and delithiation. Using the Bader scheme for topological partitioning of charge density and projected density of states (PDOS) in the electronic strucutre, we highlight the significant role of O-2p states and the relatively inert role of Fe-3d states in the charge transfer associated with delithiation. We show that 50% substitution of Fe with Al or Mg results in enhancement in the theoretical capacity of LiFeSiO4 from 173 mAhg–1 to 191 mAhg–1 (∼10%) and 193 mAhg–1 (∼12%), respectively, while maintaining its intercalation voltage and structural stability during lithiation and delithiation.  a1932-7447