The well‐established proton exchange membrane (PEM)‐based water electrolysis, which
operates under acidic conditions, possesses many advantages compared to alkaline water …

Metallic nanostructures with low dimensionality (one-dimension and two-dimension)
possess unique structural characteristics and distinctive electronic and physicochemical …

Alkaline water splitting is an attractive method for sustainable hydrogen production. Owing to
the sluggish kinetics of alkaline water reduction and oxidation, it is crucial to understand the …

Developing robust oxygen evolution reaction (OER) catalysts requires significant advances
in material design and in‐depth understanding for water electrolysis. Herein, we report …

Currently, RuO2 is a benchmark acidic oxygen evolution reaction (OER) catalyst.
Nevertheless, its wide applications are always restricted by slow dynamics and limited …

Hydrogen can be produced in a clean way from water by its electrochemical splitting. Water
electrolysis consists of two half-reactions, of which the oxygen evolution reaction (OER) is …

Proton exchange membrane water electrolysis (PEMWE) is projected to become a key
technology to enable the decarbonisation of 'hard to abate'sectors of the economy. However …

Hydrogen is a clean and renewable energy carrier for powering future transportation and
other applications. Water electrolysis is a promising option for hydrogen production from …

The development of inexpensive and efficient electrocatalysts is key to commercializing
energy-related electrocatalytic techniques such as water electrolyzers and metal-air …

With the growing demand for sustainable energy, research on electrocatalysis is attracting
more attention in the fabrication of clean energy devices (eg, fuel cells, electrolyzers, and …