Interlayer engineering of a V2O5 anode toward high-rate and durable dual-ion batteries

Dual-ion batteries (DIBs) have gained widespread attention thanks to their high operating voltage, low cost, and environmental friendliness. However, the development of DIBs is dramatically limited by the unsatisfactory rate capacity and cycling performance of anode materials. Herein, we adopted a water-incorporation approach to design a V2O5 anode with an extended interlayer gap (W-V2O5). The incorporated H2O not only offered ample space and abundant channels for efficient ion/electron intercalation/diffusion, but also improved structural stability during the repeated charge and discharge processes. Consequently, the W-V2O5 electrode delivered an enhanced specific capacity (293.2 vs. 264.4 mA h g(-1) at 1C), rate property (48.2% vs. 24.6% from 1C to 70C), and cycling stability (96.8% vs. 74.6% over 1000 cycles). Furthermore, a DIBs device with fast kinetics was assembled with a graphite cathode and W-V2O5 NS anode, which could work normally in a wide range of current densities. This work opens a new avenue for designing layered materials for energy-storage devices with high rate and good durability.

Automated summary

This study presents a novel water-incorporation approach to design V2O5 anode with an extended interlayer gap, which improves the rate capacity and cycling performance of dual-ion batteries (DIBs). The water-incorporated V2O5 electrode shows enhanced specific capacity, rate property, and cycling stability. Furthermore, a DIBs device with fast kinetics was successfully assembled, indicating the potential of this design for high-rate and durable energy-storage devices.