Insights into the conversion mechanism of the restriction strategy and self-activation enabled high-performance manganese fluoride anodes†
Abstract
Metal fluorides are expected to serve high-energy lithium-ion batteries (LIBs) owing to their prominent lithium storage capacity led by multi-electron transfer reactions. However, their slow kinetics and voltage hysteresis limit their practical utilization. Herein, carbon-coated submicron binary fluoride MnF2 (MFMC) is synthesized via a reverse-micellar microreactor and tannic acid coating to physically restrict the growth of precursors and MnF2 particles during phase formation, respectively. A novel conversion reaction in the first discharge stage is proposed, in which the mesophase Li2MnF4 can serve as an intermediate phase during the transition from MnF2 to LiF to reduce lattice strain and energy consumption, which is confirmed by first-principles density functional theory (DFT) calculations and HRTEM. More remarkably, the (110) crystal planes of Mn nanodomains refined after cycling possess an ultra-low migration barrier of 0.044 eV. Mn cooperates with the newly generated amorphous phase to accelerate the migration of Li+ into the interior of the particles, causing continuous activation of the battery. The optimized anode shows superior stability and lithium storage capacity (629 mA h gā1 after 1300 cycles at 1 A gā1). This work effectively enhances the kinetics with a feasible restriction strategy and proposes novel insights into the conversion mechanism, inspiring the design of fluoride electrodes.
- This article is part of the themed collection: Journal of Materials Chemistry A HOT Papers