Electrochemical water splitting represents one of the most promising technologies to
produce green hydrogen, which can help to realize the goal of achieving carbon neutrality …

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

The hydrogen energy generated by the electrocatalytic water splitting reaction has been
established as a renewable and clean energy carrier with ultra‐high energy density, which …

Layered double‐hydroxide (LDH) has been considered an important class of
electrocatalysts for the oxygen evolution reaction (OER), but the adsorption‐desorption …

Efficient electrochemical overall water splitting requires bi‐functional catalysts that work for
both hydrogen and oxygen evolution reactions (HER/OER). A heterostructure is thus …

Overcoming the thermodynamic and kinetic barrier of the hydrogen spillover process is of
vital significance for improving the electrocatalytic hydrogen evolution reaction (HER) activity …

Transition-metal sulfides are investigated as promising electrocatalysts for oxygen evolution
reaction (OER) in alkaline media; however, the real active species remain elusive and the …

In recent years, with the global response to the emission reduction pressure caused by
climate change, global awareness of green hydrogen has progressively grown. Electrolysis …

The development of robust nano‐and microstructured catalysts on highly conductive
substrates is an effective approach to produce highly active binder‐free electrodes for …

The development of earth-abundant and high-efficiency bifunctional electrocatalysts is
extremely desirable for electrochemical water splitting, but there are some critical challenges …