Electrochemical water splitting represents a promising technology for green hydrogen
production. To design advanced electrocatalysts, it is crucial to identify their active sites and …

Electrochemical water splitting represents one of the most promising technologies to
produce green hydrogen, which can help to realize the goal of achieving carbon neutrality …

Electrochemical water splitting is a promising technique for the production of high‐purity
hydrogen. Substituting the slow anodic oxygen evolution reaction with an oxidation reaction …

The single‐phase oxides with elemental complexity and compositional diversity, usually
named high entropy oxides, feature homogeneously dispersed multi‐metallic elements in …

Abstract Development of cost‐effective water splitting technology that allows low‐
overpotential operation at high current density with non‐precious catalysts is the key for …

Electrochemical water splitting is a critical energy conversion process for producing clean
and sustainable hydrogen; this process relies on low‐cost, highly active, and durable …

Develo** heterostructure electrocatalysts is a possible route to discovering cost-effective
and effectual catalysts for the oxygen evolution reaction. Er 2 O 3–NiO nanoparticles have …

In the societal pursuit of a carbon-neutral energy future, energy storage and conversion
technologies can play a decisive role in better utilizing sustainable energy sources such as …

Decarbonizing the chemical industry and achieving carbon-neutral energy is paramount to
the sustainability of the human species on earth. Electrocatalysis using transition metal …

Significant research is currently performed on electrochemical water splitting to solve
ecological problems and energy issues. Sustainable and eco-friendly energy systems prefer …