Proton exchange membrane water electrolysis (PEMWE), as a promising technology for
hydrogen production from renewable energy sources, has great potential for industrial …

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

Ni–Fe bimetallic electrocatalysts are expected to replace existing precious metal catalysts
for water splitting and achieve industrial applications due to their high intrinsic activity and …

Electrocatalytic water splitting (EWS) for hydrogen production is considered an ideal strategy
for utilizing renewable energy, reducing fossil fuel consumption, and addressing …

High-efficiency electrocatalysts are crucial for a fossil fuel-free future. Although many
strategies have been proposed to boost the electrocatalysts' performance, efficient and cost …

Transition metal phosphides as ideal anodes have been attracted a large number of
interests due to their excellent performance for lithium-ion batteries. Nevertheless, CoMoP2 …

Transition metal oxides are well-known for their excellent activity and stability during oxygen
evolution reaction process, while their hydrogen evolution reaction performance still is …

The hydrogen evolution reaction (HER) using earth-abundant noble-metal-free catalysts has
gained substantial interest in electrocatalytic water splitting technologies, particularly in …

The rapidly growing global need for environmentally friendly energy solutions has inspired
extensive research and development efforts aimed at harnessing the potential of hydrogen …

The synthesis of electrocatalysts which used simultaneously as electrodes for the hydrazine
oxidation reaction (HzOR), and hydrogen evolution reaction (HER) can significantly improve …