Direct electrolytic splitting of seawater for the production of H 2 using ocean energy is a
promising technology that can help achieve carbon neutrality. However, owing to the high …

Directly seawater electrolysis would be a transformative technology for large‐scale carbon‐
neutral hydrogenproduction without relying on pure water. However, current seawater …

Seawater splitting requires highly active and stable electrocatalysts to sustain electrolysis
without chloride corrosion, especially for the anode. Herein, a boron (B) doped MnFe 2 O 4 …

Electrochemical water splitting plays a vital role in facilitating the transition towards a
sustainable energy future by enabling renewable hydrogen (H2) production, energy storage …

Electrodes are key components in water splitting. Owing to their porous structures,
commercial foam metal electrode matrices can provide numerous active sites. However, the …

Electrochemical seawater splitting is a potentially attractive technology for sustainable
hydrogen production; however, its implementation is severely hindered by the lack of active …

Direct electrolysis of inexhaustible seawater to generate green hydrogen represents a more
environment‐friendly technology relative to freshwater electrolysis. However, current …

Inverse spinels with characteristic structures are one of the most popular electrocatalytic
materials, but typically have limited intrinsic activities for oxygen evolution reactions (OER) …

The characteristics of FeCoNiCrMn high entropy alloy lead to great significance in
electrocatalytic oxygen evolution reaction (OER) of water splitting. However, the preparation …

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