Seawater electrolysis is an attractive way of making H2 in coastal areas, and NiFe‐based
materials are among the top options for alkaline seawater oxidation (ASO). However, ample …

Seawater electrolysis emerges as a viable solution for sustainable hydrogen production,
leveraging areas abundant in renewable energy but scarce in freshwater. However, the …

Electrocatalysis represents an efficient and eco‐friendly approach to energy conversion,
enabling the sustainable synthesis of valuable chemicals and fuels. The deliberate …

To achieve clean and sustainable energy development, the thermodynamically favourable
electrocatalytic oxidation reaction of biomass derivatives can be combined with electrolysis …

Combining an electrochemically stable material onto the surface of a catalyst can improve
the durability of a transition metal catalyst, and enable the catalyst to operate stably at high …

Seawater electrolysis, especially in coastlines, is widely considered as a sustainable way of
making clean and high-purity H2 from renewable energy; however, the practical viability is …

Seawater electrolysis is a promising but challenging strategy to generate carbon‐neutral
hydrogen. A grand challenge for hydrogen evolution reaction (HER) from alkaline seawater …

Gas‐evolving reactions (GERs) are important in many electrochemical energy conversion
technologies and chemical industries. The operation of GERs at high current densities is …

Producing green hydrogen from abundant natural resources such as seawater and human
urine is a viable solution for energy and industrial applications. However, the field of …

Due to the high cost of ultra‐pure water supply and the mismatch between water sources
and renewable energy distribution, the large‐scale production of green hydrogen through …