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 …

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 …

Ion mobility is a critical performance parameter not only in electrochemical energy storage
and conversion but also in other electrochemical devices. On the basis of first-principles …

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

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 …

Dendrite formation is an important issue for the metal anode-based battery system. The
traditional perception that Mg metal anode does not grow dendrite during operation has …

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

Electrochemical energy storage has experienced unprecedented advancements in recent
years and extensive discussions and reviews on the progress of multivalent metal‐ion …

Owing to its exceptional chemical stability and proton conductivity, perfluorosulfonated
ionomer (Nafion) is widely used as a polymer electrolyte in many electrochemical devices …

Rechargeable magnesium (Mg) batteries are promising beyond Li-ion technologies due to
their high volumetric capacity (3832 mAh cm–3) and high natural abundance. Nonetheless …