A Safer High-Energy Lithium-Ion Capacitor Using Fast-Charging and Stable ω-Li V O Anode.

Lithium-ion capacitors (LICs) are flourishing toward high energy density and high safety, which depend significantly on the performance of the intercalation-type anodes used in LICs. However, commercially available graphite and Li Ti O anodes in LICs suffer from inferior electrochemical performance and safety risks due to limited rate capability, energy density, thermal decomposition, and gassing issues. Here a safer high-energy LIC based on a fast-charging ω-Li V O (ω-LVO) anode with a stable bulk/interface structure is reported.

Precisely Tunable T-NbO Nanotubes via Atomic Layer Deposition for Fast-Charging Lithium-Ion Batteries.

The demand for fast-charging of lithium-ion batteries (LIBs) in modern electric transportation and wearable electronics is rapidly growing. However, commercially available graphite anodes still suffer from slow kinetics of lithium-ion diffusion and severe safety concerns of lithium plating when achieving the fast-charging goal. Here, it is demonstrated that the Li-ion diffusion kinetics of orthorhombic NbO nanotubes (T-NbO NTs) is enhanced by atomically precise manufacturing of nanoarchitectures.