Lithium-ion batteries are the state-of-the-art power source for most consumer electronic
devices. Current collectors are indispensable components bridging lithium-ion batteries and …

Lithium metal anodes are an appealing choice for rechargeable batteries due to their
exceptionally high theoretical capacity of about 3860 mA hg− 1. However, the uneven …

The energy density of lithium metal batteries (LMBs) could be much higher than that of
current graphite anode-based LIBs. When a metallic current collector is used for plating/de …

Although the lithium‐metal anode (LMA) can deliver a high theoretical capacity of≈ 3860
mAh g− 1 at a low redox potential of− 3.040 V (vs the standard hydrogen electrode), its …

The organic–inorganic interfaces can enhance Li+ transport in composite solid‐state
electrolytes (CSEs) due to the strong interface interactions. However, Li+ non‐conductive …

Lithium metal anode of lithium batteries, including lithium-ion batteries, has been considered
the anode for next-generation batteries with desired high energy densities due to its high …

Lithium metal is the “holy grail” anode for next‐generation high‐energy rechargeable
batteries due to its high capacity and lowest redox potential among all reported anodes …

Rechargeable Li metal batteries once had a glory moment in 1980s, but its development
was sooner suspended for safety concerns from dendrite formation. After falling into oblivion …

A 3D host decorated with lithiophilic sites has emerged as a promising strategy to stabilize
lithium metal anode by guiding uniform Li deposition and relieving volume fluctuations …

Abstract Alkali metals (ie, Li, Na, and K) are promising anode materials for next‐generation
high‐energy‐density batteries due to their superior theoretical specific capacities and low …