The limited availability of freshwater in renewable energy-rich areas has led to the
exploration of seawater electrolysis for green hydrogen production. However, the complex …

Proton exchange membrane (PEM) water electrolysis is recognized as the most promising
technology for the sustainable production of green hydrogen from water and intermittent …

Earth-abundant, acid-stable catalysts for the oxygen evolution reaction are essential for
terawatt-scale hydrogen production using proton exchange membrane (PEM) electrolysers …

Glycerol (electrochemical) oxidation reaction (GOR) producing organic small molecule acid
and coupling with hydrogen evolution reaction is a critical aspect of ensuring balanced …

It is vital to explore effective ways for prolonging electrode lifespans under harsh electrolysis
conditions, such as high current densities, acid environment, and impure water source. Here …

Using abundant seawater electrolysis to generate hydrogen is a sustainable alternative to
increasingly matured freshwater electrolysis. In a recent issue of Nature, Xie, Shao, and co …

Recently, hydrogen energy has been significantly investigated by numerous technologies.
To date, noble platinum group metals have often been employed to fabricate working …

Researchers have been seeking for the most technically‐economical water electrolysis
technology for entering the next‐stage of industrial amplification for large‐scale green …

The stability of electrocatalysts is a concern for nearly all materials; degradation can occur
via dissolution, leaching, sintering, amorphization, or reduction/oxidation processes …

The development of electrocatalysts that are not reliant on iridium for efficient acid‐oxygen
evolution is a critical step towards the proton exchange membrane water electrolysis …