The lithium (Li) metal anode (LMA) is susceptible to failure due to the growth of Li dendrites
caused by an unsatisfied solid electrolyte interface (SEI). With this regard, the design of …

Lithium-metal batteries with high energy/power densities have significant applications in
electronics, electric vehicles, and stationary power plants. However, the unstable lithium …

Magnesium-based batteries represent one of the successfully emerging electrochemical
energy storage chemistries, mainly due to the high theoretical volumetric capacity of metallic …

Lithium (Li) metal is promising for high energy density batteries due to its low
electrochemical potential (− 3.04 V) and high specific capacity (3860 mAh g− 1). However …

Solid electrolyte interphase (SEI), known as an ionic conductor but electronic insulator, plays
a dominant role in cycling stability and safety of rechargeable lithium metal batteries …

Lithium metal anodes have the potential to be a disruptive technology for next-generation
batteries with high energy densities, but their electrochemical performance is limited by a …

Li dendrite formation deteriorates cyclability and poses a safety hazard, hindering the
widespread use of Li metal as the ultimate anode material for post‐Li‐ion batteries. Hence …

The formation of dendrites on lithium electrodes presents safety and cycling challenges for
the development of high-performance, rechargeable lithium metal batteries. While a …

Owing to the high abundance and gravimetric capacity (1165.78 mAh g− 1) of pure sodium,
it is considered as a promising candidate for the anode of next‐generation batteries …

The lifetime and health of lithium metal batteries are greatly hindered by nonuniform
deposition and growth of lithium at the anode–electrolyte interface, which leads to dendrite …