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

Directly splitting seawater to produce hydrogen provides a promising pathway for energy
and environmental sustainability. However, current seawater splitting faces many …

The corrosive anions (eg, Cl−) have been recognized as the origins to cause severe
corrosion of anode during seawater electrolysis, while in experiments it is found that natural …

The development of highly efficient non‐precious metal electrocatalysts for the oxygen
evolution reaction (OER) in low‐grade or saline water is currently of great importance for the …

Hydrogen production employing seawater electrolysis is a sustainable strategy for future
energy prospects. This study reports high-performance bifunctional water (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 …

Electronic structure engineering lies at the heart of the catalyst design, however, utilizing
one strategy to modify the electronic structure is still challenging to achieve optimal …

To realize highly efficient and stable hydrogen production at high current densities, more
efforts are devoted to develo** outstanding water-splitting electrocatalysts. Herein …

Owing to the presence of a substantial concentration of chlorine in seawater, the anode still
faces severe chlorine corrosion, especially the water splitting operated at high current …

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