Electrodeposited of ultrathin VOx-doped NiFe layer on porous NiCo phosphide for efficient overall water splitting

Abstract: An ultrathin VOx-doped NiFe alloy layer (VOx@NiFe) was electrodeposited on the surface of nickel-cobalt phosphide (NiCoP) supported by titanium mesh (TM) to achieve a highly active and low-cost bifunctional electrocatalyst for overall water splitting. VOx doping not only significantly enhances the electrochemical surface areas and the concentration of oxygen vacancies in the NiFe/NiCoP/TM composite, but also greatly improves the surface hydrophilicity. The VOx@NiFe/NiCoP/TM electrode retains a 3D porous struct… Show more

“…This finding suggested that N-doping could endow the electrode surface with superior wettability, thereby facilitating the dissipation of gas bubbles and improving the catalytic performance significantly. 36 In situ conversion reconstructed the morphology into a 3D nanosheet network and provided an enlarged specific surface area for abundant active sites. The optimal monolithic electrode yielded massive oxygen bubbles under high current density.…”

A facile N-doped NiFe(B) (Oxy)hydroxide monolithic electrode for enhanced water oxidation

“…This finding suggested that N-doping could endow the electrode surface with superior wettability, thereby facilitating the dissipation of gas bubbles and improving the catalytic performance significantly. 36 In situ conversion reconstructed the morphology into a 3D nanosheet network and provided an enlarged specific surface area for abundant active sites. The optimal monolithic electrode yielded massive oxygen bubbles under high current density.…”

A facile N-doped NiFe(B) (Oxy)hydroxide monolithic electrode for enhanced water oxidation

Vanadium Oxide: Phase Diagrams, Structures, Synthesis, and Applications

Materials for renewable fuels production