Li metal anode attracts tremendous attention in next‐generation battery systems with high
energy density, but volume change and dendritic growth limit its practical applications …

Lithium (Li) metal is strongly considered to be the ultimate anode for next-generation high-
energy-density rechargeable batteries due to its lowest electrochemical potential and …

The lithium polysulfide (LiPSs) shuttling and slow chemical reactions at the sulfur cathode
and the formation of dendritic lithium in metal anodes severely hinder the popularization of …

Lithium nitrate is an attractive lithium additive in the construction of high‐performance lithium
metal anodes with a Li3N‐rich solid electrolyte interphase (SEI) layer. However, the eight …

Solid polymer composite electrolytes possess the benefits of superior compatibility with
electrodes and good thermal characteristics for more secure energy storage equipment …

Constructing a multi-functionally artificial interphase layer is an emerging strategy to
possibly address the issues of inhomogeneous Lithium (Li) nucleation and dendrite growth …

The high theoretical capacity of silicon (Si) makes it an attractive anode for lithium-ion
batteries (LIBs). However, the poor cycle performance due to the volumetric expansion of Si …

For wide and safe applications of Li metal batteries, the suppression of Li dendrite growth
during cycling is the most crucial yet challenging topic. In this work, an artificial protective …

Dendrite growth hinders the practical uses of the lithium metal anode (LMA) toward a high-
energy-density battery. From the mechanics perspective, the lithium growth on a solid …

A brief overview of recent developments in the formation, detection, and suppression of
lithium dendrites in carbon-based lithium-ion batteries is presented. The electrochemical …