Honeycomb-like porous iron fluoride hybrid nanostructures: excellent Li-storage properties and investigation of the multi-electron reversible conversion reaction mechanism

Iron fluoride cathodes with good specific energy/power performance can hardly operate durably at room temperature due to poor conductivity and sluggish kinetics. Fabricating novel hybrid nanostructures is a promising approach to obtain a fast diffusion and transport process. In this study, a porous honeycomb-like iron fluoride hybrid composite comprising iron fluoride nanocrystals (similar to 1-4 nm) encapsulated in separate carbon nests constructed by multi-scale pores (similar to 1-100 nm) was fabricated through a combination of room-temperature fluorination and a mild annealing process for the first time. The iron fluoride topochemically evolved from a smaller iron oxide nanocrystal precursor (similar to 2-3 nm) is closely engineered with carbon creases nested in carbon microbubbles (CMBs) which exhibit a three dimensional (3D) porous honeycomb-like network structure. As a cathode material for lithium-ion batteries (LIBs), the hybrid electrode delivers a large capacity of nearly 500 mA h g(-1) at 20 mA g(-1) (normalized to the composite, i.e. the capacity is calculated based on the total mass of the composite). Meanwhile, a durable cyclability of more than 500 cycles and a large rate of 10 A g(-1) were also realized at room temperature. The impressive specific energy/power performance (1100 W h kg(-1)/224 W kg(-1)) which is superior to that of today's Li-ion batteries (similar to 380 W h kg(-1)/similar to 80 W kg(-1)) reveals the efficiency of the novel hybrid nanostructure in speeding up the kinetics without sacrificing the storage capability. Direct insights into the lithiation process reveal that iron fluoride firstly undergoes a mild amorphization process, and then crystallizes as g-Fe nanocrystals after in-depth lithiation; during the de-lithiation process, g-Fe firstly becomes amorphous due to the injection of fluorine, and subsequently evolves into double-salt-like LixFeFy nanocrystals for further fluorine enriching. Reversible conversion between C-Fe-0/LiF and T-FeF2, like LixFe3+Fy with a 3 mole electron transfer, lasts for more than 100 cycles without any obvious re-distribution of the active materials.