Abstract Lithium–air (Li–air) batteries stand out among the post‐Li‐ion batteries due to their
high energy density, which has rapidly progressed in the past years. Regarding the …

The consumption of fossil fuels has contributed to global warming and other problems. It is
urgent to exploit progressive, low‐cost, and environmentally friendly energy storage devices …

Lewis‐base sites have been widely applied to regulate the properties of Lewis‐acid sites in
electrocatalysts for achieving a drastic technological leap of lithium‐oxygen batteries …

Wide adaptation of intermittent renewable energies into the power grid and more affordable
electric vehicles cannot be realized without low-cost, high-energy, and long-life energy …

Metal-organic frameworks (MOFs) are considered as promising oxygen electrode materials
for lithium-oxygen (Li-O 2) batteries. However, their structure-activity relationship in …

Although lithium–oxygen batteries have attracted attention due to their extremely high
energy densities, rational design, and critical evaluation of high‐energy‐density cathode for …

The major challenges for Li‐O2 batteries are sluggish reaction kinetics and large
overpotentials due to the cathode passivation resulting from insulative and insoluble Li2O2 …

Aprotic lithium‐oxygen (Li‐O2) batteries represent a promising next‐generation energy
storage system due to their extremely high theoretical specific capacity compared with all …

In the pursuit of a highly reversible lithium–oxygen (Li–O2) battery, control of reaction sites to
maintain stable conversion between O2 and Li2O2 at the cathode side is imperatively …

Aprotic lithium-oxygen (Li-O2) batteries have a high theoretical energy density, but they face
challenges such as cathode blockage, high charge overpotential, and poor cycling stability …