Serrated lithium fluoride nanofibers-woven interlayer enables uniform lithium deposition for lithium-metal batteries

The uncontrollable formation of Li dendrites has become the biggest obstacle to the practical application of Li-metal anodes in high-energy rechargeable Li batteries. Herein, a unique LiF interlayer woven by millimeter-level, single-crystal and serrated LiF nanofibers (NFs) was designed to enable dendrite-free and highly efficient Li-metal deposition. This high-conductivity LiF interlayer can increase the Li+ transference number and induce the formation of 'LiF-NFs-rich' solid-electrolyte interface (SEI). In the 'LiF-NFs-rich' SEI, the ultra-long LiF nanofibers provide a continuously interfacial Li+ transport path. Moreover, the formed Li-LiF interface between Li-metal and SEI film renders low Li nucleation and high Li+ migration energy barriers, leading to uniform Li plating and stripping processes. As a result, steady charge-discharge in a Li//Li symmetrical cell for 1600 h under 4 mAh cm(-2) and 400 stable cycles under a high area capacity of 5.65 mAh cm(-2) in a high-loading Li//rGO-S cell at 17.9 mA cm(-2) could be achieved. The free-standing LiF-NFs interlayer exhibits superior advantages for commercial Li batteries and displays significant potential for expanding the applications in solid Li batteries. A unique lithium fluoride interlayer woven by millimeter-level, single-crystal and serrated nanofibers enables uniform Li metal plating/stripping behaviors, effectively promoting the application of high-energy and high-safety Li metal batteries.

Automated summary

By designing a unique LiF interlayer woven by millimeter-level, single-crystal and serrated nanofibers, the uncontrollable formation of Li dendrites can be overcome, leading to improved performance and reliability of Li-metal batteries.