Abstract Metal anodes (Li, Na, K, Zn, Mg, Ca, Fe, Al, Mn, etc) based on a plating/stripping
electrochemical mechanism have attracted great attention in rechargeable batteries …

Much theoretical effort has been spent on the causes of dendrite formation in lithium metal
batteries, but a decisive factor has been overlooked: Lithium is deposited on an electrode …

Despite the substantial efforts aimed at suppressing metallic dendrite growth in Li-metal
batteries, Mg-metal dendrite growth has thus far received relatively little attention, and the …

Electroplating is one of the most common processes to create smooth surfaces and thin
coatings, but achieving smooth lithium (Li) plating without Li dendrite growth remains a …

One of the greatest challenges toward rechargeable magnesium batteries is the
development of noncorrosive electrolyte solutions with high anodic stability that can support …

This study introduces laser irradiation into the electrodeposition of Cu-Al 2 O 3 composite
coatings. The cavitation bubble generated by laser breakdown in the solution caused strong …

Li, Na, and K metal anodes are the most promising anodes for post Li ion batteries because
of their low redox potential and high specific capacity. However, alkali metals suffer from …

Electrochemical stability is a critical performance parameter for the materials used as
electrolytes and electrodes in batteries. Using first-principles electronic structure …

Due to its high theoretical energy density and relative abundancy of active materials, the
magnesium–sulfur battery has attracted research attention in recent years. A closely related …

Magnesium batteries, like lithium‐ion batteries, with higher abundance and similar
efficiency, have drawn great interest for large‐scale applications such as electric vehicles …