MOFs are constructed by self-assembly of metal ions/clusters and organic linkers. They have
received much attention owing to the benefits of well-exposed active sites, ultrahigh porosity …

Lithium–air batteries (LABs) have attracted extensive attention due to their high theoretical
energy density based on the “Holy Grail”, the lithium metal anode and the inexhaustible air …

The compositing strategy offers great potential in designing bifunctional oxygen
electrocatalysts for Zn–air batteries. Recent reports reveal that the couple of RuO2, serving …

Lithium–air batteries (LABs) have attracted intense interest due to their ultrahigh energy
density. However, the performance of LABs has to depend on modified electrolytes, gas …

Electrochemical water splitting, as a promising energy conversion technology, is entirely
limited by the slow reaction kinetics due to the large overpotentials for oxygen evolution …

Rechargeable Zn–air batteries, which combine the key features of secondary batteries and
fuel cells, have been regarded as the next-generation energy storage/conversion device in …

Composite strategies for constructing dual-atom sites at the hetero-interface provide
considerable prospects for designing efficient bifunctional oxygen catalysts. Given the …

Solid‐state lithium–air batteries (SSLABs) have become the focus of next‐generation
advanced batteries due to their safety and high energy densities. Current research on …

Li–air batteries are a promising type of energy storage technology because of the ultra-high
theoretical specific energy. Great advances are made in recent years, including the …

The sluggish oxygen reduction/evolution reaction (ORR/OER) kinetics greatly limits the
application of zinc-air batteries (ZAB). Regarding this, searching for high-efficient …