Metal-Organic Framework-Derived Nanoconfinements of CoF2 and Mixed-Conducting Wiring for High-Performance Metal Fluoride-Lithium Battery

Metal fluoride (MF) conversion cathodes theoretically show higher gravimetric and volumetric capacities than Ni- or Co-based intercalation oxide cathodes, which makes metal fluoride-lithium batteries promising candidates for next-generation high-energy-density batteries. However, their high-energy characteristics are clouded by low-capacity utilization, large voltage hysteresis, and poor cycling stability of transition MF cathodes. A variety of reasons is responsible for this: poor reaction kinetics, low conductivities, unstable MF/electrolyte interfaces and dissolution of active species upon cycling. Herein, we combine the synthesis of the metal-organic-framework (MOF) with the low-temperature fluorination to prepare MOF-shaped CoF2@C nanocomposites that exhibit confinement of the CoF2 nanoparticles and efficient mixed-conducting wiring in the produced architecture. The ultrasmall CoF2 nanoparticles (5-20 nm on average) are uniformly covered by graphitic carbon walls and embedded in the porous carbon framework. Within the CoF2@C nanocomposite, the cross-linked carbon wall and interconnected nanopores serve as electron- and ion-conducting pathways, respectively, enabling a highly reversible conversion reaction of CoF2. As a result, the produced CoF2@C composite cathodes successfully restrain the above-mentioned challenges and demonstrate high-capacity utilization of , similar to 500 mAh g(-1) at 0.2C, good rate capability (up to 2C), and long-term cycle stability over 400 cycles. Overall, the presented study not only reports on a simple composite design to achieve high-energy characteristics in CoF2-Li batteries but also may provide a general solution for many other metal fluoride-lithium batteries.

Automated summary

Metal fluoride (MF) conversion cathodes have the potential to be high-energy-density batteries, but face challenges such as low capacity utilization, large voltage hysteresis, and poor cycling stability. By combining metal-organic-framework (MOF) synthesis with low-temperature fluorination, CoF2@C nanocomposites were developed, providing stable electron- and ion-conducting pathways for a highly reversible conversion reaction of CoF2. This approach not only achieves high-capacity utilization, good rate capability, and long-term cycle stability in CoF2-Li batteries, but also offers a general solution for other metal fluoride-lithium batteries.