Alkaline water electrolysis is a central technology to produce large-scale green hydrogen, a
zero-emission energy carrier. Great progress has been made on electrocatalyst …

High entropy materials (HEM) have been attracting much attention as emerging catalysts for
electrochemical water splitting. HEM catalysts have unique properties such as an interesting …

Efficient and durable electrocatalysts fabricated by using nanosized nonprecious-metal-
based materials have attracted considerable attention for use in the oxygen evolution …

Urea electrooxidation holds significant promise for addressing the slow anodic oxygen
evolution reaction (OER) in water splitting due to its favorable thermodynamic potential …

Electrocatalytic water splitting is an efficient method for producing high purity hydrogen and
has the advantage of emitting zero waste. Manganese phosphides are considered to be …

High-valent Mo-based oxides are easily dissolved in alkaline electrolyte resulting in
complete surface reconstruction of catalyst. Therefore, there are few researches on the …

Hydrogen evolution and oxidation are critical to realizing hydrogen energy recycling and to
the hydrogen economy. Therefore, it is important to develop non-precious metal catalysts …

The construction of heterojunctions is commonly regarded as an efficient way to promote the
production of hydrogen via photocatalytic water splitting through the enhancement of …

A cross-linked molecularly imprinted polymer (MIP) was synthesized and functionalized by
metal oxide nanoparticles (TiO 2 and SiO 2) to form a potential cross-linked (MIP) …

One of the promising technologies for green hydrogen production is seawater electrolysis
using an anion exchange membrane (AEM) electrolyzer. To overcome the use of precious …