Ultrathin δ-MnO 2 nanoflakes with Na + intercalation as a high-capacity cathode for aqueous zinc-ion batteries.

Pristine δ-MnO 2 as the typical cathode for rechargeable zinc-ion batteries (ZIBs) suffers from sluggish reaction kinetics, which is the key issue to prepare high-performance manganese-based materials. In this work, Na + incorporated into layered δ-MnO 2 (NMO) was prepared for ZIB cathodes with high capacity, high energy density, and excellent durable stability. By an effective fabricated strategy of hydrothermal synthesis, a three-dimensional interconnected δ-MnO 2 nanoflake network with Na + intercalation showed a uniform array arrangement and high conductivity. Also, the H + insertion contribution in the NMO cathode to the discharge capacity confirmed the fast electrochemical charge transfer kinetics due to the enhanced ion conductivity from the insertion of Na + into the interlayers of the host material. Consequently, a neutral aqueous NMO-based ZIB revealed a superior reversible capacity of 335 mA h g -1 , and an impressive durability over 1000 cycles, and a peak gravimetric energy output of 459 W h kg -1 . As a proof of concept, the as-fabricated quasi-solid-state ZIB exhibited a remarkable capacity of 284 mA h g -1 at a current density of 0.5 A g -1 , and good practicability. This research demonstrated a significant enhancement of the electrochemical performance of MnO 2 -based ZIBs by the intercalation of Na + to regulate the microstructure and boost the electrochemical kinetics of the δ-MnO 2 cathode, thus providing a new insight for high-performance aqueous ZIBs.