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 …

H 2 has a sufficiently high energy density and a combustion process that emits no carbon,
therefore being an appealing storable alternative to fossil fuels. With evident advantages of …

Green hydrogen production from renewably powered water electrolysis is considered as an
ideal approach to decarbonizing the energy and industry sectors. Given the high-cost supply …

Seawater electroreduction is attractive for future H2 production and intermittent energy
storage, which has been hindered by aggressive Mg2+/Ca2+ precipitation at cathodes and …

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

Water electrolysis powered by renewable energy could provide green hydrogen energy that
has significant potential to build a near-zero-emission society. In addition to factors such as …

Direct seawater electrolysis is a promising technology for massive green hydrogen
production but is limited by the lack of durable and efficient electrocatalysts toward the …

The prospective of exploring “abundantly available electrolytes”, ie seawater, as an
electrolyte feedstock in electrolyzers is realized recently for supplying unlimited and …

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

Direct electrochemical seawater splitting is a renewable, scalable, and potentially economic
approach for green hydrogen production in environments where ultra‐pure water is not …