Abstract
Aqueous batteries hold promise for grid energy storage for their intrinsic safety and cost effectiveness. Suppressing water electrolysis is a prime consideration, while the round-trip efficiency is an often-overlooked issue. Here, we report an aqueous alkaline dual-ion battery with Na + and OH − intercalating anode and cathode. Despite the oxygen-evolving cathode, the battery exhibits high Coulombic efficiency because oxygen evolution is suppressed by asymmetric anode and cathode polarization. Together with the low voltage loss, the battery yields a high round-trip efficiency of 77.7% at 1 A g −1 . Other merits of this battery include moderate energy density and the use of safe, harmless, and cheap materials, manifesting a practical choice for grid energy storage. The ultra-fast intercalation reactions also endow the battery with high-rate performances comparable to supercapacitors. Moreover, this work proposes and verifies the concept of asymmetric electrode polarization, shifting the paradigm for electrode selection in aqueous batteries. • Aqueous alkaline dual-ion battery with Na + and OH − intercalation chemistry • Asymmetric anode and cathode polarization inhibits OER on cathode • The battery shows high Coulombic and round-trip efficiency • Battery-type charge-discharge curves and supercapacitor-type rate capability Xu et al. demonstrate an aqueous alkaline battery with Na + and OH − intercalation chemistry. The rapid and reversible reactions yield low voltage loss, while the asymmetric anode and cathode polarization inhibits the cathodic OER, altogether leading to high round-trip efficiency. The battery has a constant voltage but supercapacitor-type, high-power density.
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