Themed collection FOCUS: Electrocatalytic Hydrogen Evolution

P-NiSe/MoSe₂ exhibits excellent HER properties due to the modulation of the electronic structure by P doping and the synergistic effect arising from the heterostructure.

1D bifunctional RuO₂/Ru-CNFs-350 catalyst is fabricated to show high activity and remarkable durability toward both OER and HER due to the formation of a RuO₂/Ru heterostructure and the carbon substrate.

Ru nanoparticles coordinated with O supported on a carbon matrix were synthesized. The electron communication between Ru and O accelerated the charge transfer and thus improved the electrocatalytic hydrogen production activity.

Bifunctional atomically dispersed ruthenium electrocatalysts with a low metal loading (0.2 wt%) exhibit outstanding performance for bipolar membrane water electrolysis.

The designed Mn-modified CoS₂ catalyst exhibits outstanding bifunctional electrocatalytic performances toward hydrogen evolution reaction and hydrazine oxidation reaction for high-efficiency energy-saving H₂ production by water-assisted electrolysis.

Surface reconstruction in NiMoO₄–CoO nanosheet catalyst through Mo dissolution with subsequent formation of K₂Mo₃O₁₀ is disclosed, which brings more active sites and enhanced charge transfer, and boosts intrinsic HER activity per catalysis site.

A multi-level spatial confinement strategy is proposed for the fabrication of ultra-dispersed 1T-Co-MoS₂ nanoclusters, which exhibit remarkable electrocatalytic activity and durability for HER.

Crystal–amorphous NiO/MoO₂ with a coupled high-density and well-dispersed heterojunction has been designed to tailor the charge distribution to lower the reaction energy barrier for the HER.

Phosphorus doped two-dimensional CoFe₂O₄ nanobelts decorated with Ru and CoFe hydroxide clusters on iron foam (CoFeO_xH_y–Ru/P–CoFe₂O₄/IF) are synthesized as efficient electrocatalysts for the highly electrocatalytic HER.

Benefiting from an abundant interface with many active sites, robust interaction and synergistic effect between FeS₂ and MXene, FeS₂@MXene exhibits remarkable catalytic activity towards water splitting in alkaline electrolytes.

NiFeMn alloy@NiFeMn oxyhydroxide was fabricated by electrodeposition, which reveals exceptional electrocatalytic property toward overall water splitting owing to the extraordinary multi-level structure.

Square planar 1, square pyramidal 2 and trigonal bipyramidal 3 copper complexes are poor catalysts for hydrogen evolution (HER) under photocatalytic conditions, whereas 1 is, or forms, a good and enduring electrocatalyst for HER, but 2 and 3 do not.