materials in dilute aqueous electrolytes, respectively, [7] although a common strategy for adjusting the operating window is to change the pH of the electrolyte. However, even in strongly alkaline electrolytes (pH = 14), hydrogen evolution still occurs at 2.213 V, which is too high to accommodate most of the anode materials desired by battery scientists. [8] Additionally, a downshift in O 2 evolution potential will occur simultaneously when the pH is increased, keeping the gap between the anodic and cathodic limits constant at 1.23 V. This gap, known as the electrochemical stability window in aqueous electrolytes under thermodynamic equilibria, is defined by the Pourbaix diagram. The slightly higher voltage gap of 1.8 V that has been realized in existing aqueous battery setups is the result of "kinetic overpotentials" of H 2 or O 2 evolutions, which depends on changing the salt concentration, catalytic activity of the electrodes, and applied currents. [9] As a result, very few suitable electrode materials have been reported for AIBs at present, and their energy densities are still far from those required for practical applications. A particular challenge is that O 2 or H 2 evolution will result in low energy efficiencies, which is of vital importance for this technology. [10] The working potential of lithium-ion battery electrode materials is also far beyond the thermodynamic stability limits of organic electrolytes. [11] Hence, solvent molecules coordinated with Li + to form solvation shells can suffer from decomposition when ions move between electrode surfaces during the charging/discharging processes. These decomposition reactions produce dense, solid products that deposit on electrode surfaces to form a solid-electrolyte interface (SEI), which prevents direct contact between the electrodes and electrolytes. [12] A large number of inorganic salts or precipitates originating from salt reductions may also be present in the SEI at the anode, making it insulating to long-range electron transport but conductive to ions. Therefore, it can prevent sustained electrolyte decomposition while still allowing electrochemical reactions to proceed. The presence of an SEI substantially expands the usable electrochemical stability window of nonaqueous electrolytes. [13] However, protective interfaces are not formed in conventional aqueous electrolytes, because the decomposition products from coordinated water mostly are gases such as H 2 and O 2 , which will escape from the electrolyte on formation. [2] Unfortunately, traditional inorganic lithium salts such as Li 2 SO 4 , LiCl, and LiNO 3 are stable enough to be reduced Aqueous lithium/sodium-ion batteries (AIBs) have received increasing attention because of their intrinsic safety. However, the narrow electrochemical stability window (1.23 V) of the aqueous electrolyte significantly hinders the development of AIBs, especially the choice of electrode materials. Here, an aqueous electrolyte composed of LiClO 4 , urea, and H 2 O, which allows the electrochemical stability windo...
