Electrochemical water splitting technology for producing “green hydrogen” is important for
the global mission of carbon neutrality. Electrocatalysts with decent performance at high …

Oxygen reduction and evolution reactions constitute the core process of many vital energy
storage or conversion techniques. However, the kinetic sluggishness of the oxygen redox …

The need for enhanced energy storage and improved catalysts has led researchers to
explore advanced functional materials for sustainable energy production and storage …

The oxygen evolution reaction (OER) is a critical electrochemical reaction in water splitting
and rechargeable metal–air batteries. It plays a pivotal role in achieving high-efficiency …

The energy efficiency of metal–air batteries and water‐splitting techniques is severely
constrained by multiple electronic transfers in the heterogenous oxygen evolution reaction …

It is highly desirable to develop efficient catalysts under high-current-density operation and
long-term stability for high performance water splitting. However, most reported modified …

Over the past few decades, development of electrocatalysts for energy applications has
extensively transitioned from trial-and-error methodologies to more rational and directed …

As an extension of single-atom catalysts (SACs), diatomic catalysts (DACs) perfectly inherit
the advantages of SACs but break some theoretical limitations of SACs due to the interaction …

Designing metal‐organic framework (MOF)‐based catalysts with superior oxygen evolution
reaction (OER) activity and robust durability simultaneously is highly required yet very …

Designing highly active and bifunctional oxygen reduction reaction (ORR) and oxygen
evolution reaction (OER) catalysts has attracted great interest toward metal–air batteries …