화학공학소재연구정보센터
Canadian Journal of Chemical Engineering, Vol.97, No.8, 2196-2210, 2019
Fe3+ reduction during melt-synthesis of LiFePO4
LiFePO4 (LFP) is a safe and low cost cathode material for Li-ion batteries. Its solid-state synthesis requires micron-sized reactants yielding high production costs. Here, we melt-synthesized up to 5 kg batches of LFP from low-cost coarse Fe2O3 (509 mu m) in an induction furnace. Graphite from the crucible was an effective reducing agent. Adding metallic Fe or CO increased the Fe2+ content and reaction kinetics. Metallic Fe improves the lifetime of the graphite crucible but requires a premixing step for it to be effective, otherwise the Fe powder agglomerates due to the presence of a eutectic in the LiPO3-Fe-Fe2O3 system. In a pushout furnace configuration, for an hour-long holding period, injecting CO into the melt increased the Fe2+ content from 0.301 to 0.315 g/g, which we attributed to melt protection. Likewise, graphite powder floating on top of the melt further improved the Fe2+ content to 0.331 g/g. The Fe2+ content reached 0.325 g/g when using fine Fe3+ (142 mu m) and CO as reducing agent at half the holding period at 1150 degrees C. We attribute the higher reaction rate to the improved contact between the suspended Fe3+ and the CO reducing gas. When the graphite crucible is the unique reducing agent, the reaction rate was proportional to the crucible base surface area. A zero-order kinetic model characterized the solids disappearance with time. A thermal model developed to compare lab-scale data against small pilot-scale demonstrated that the charge lagged the furnace temperature by as much as 22 min at 1000 degrees C.