Tailored work function via activated interfacial electron transfer for boosting hydrogen production coupled with electrochemical glycerol oxidation.

Developing high-performance electrocatalysts for glycerol-assisted water splitting is highly imperative for the applications in energy-saving hydrogen production coupled by valorizing biomass-derived feedstocks. Interface engineering, an effective strategy for tuning the interfacial electronic structures, enables the electrochemical performance improvement, while the precise control on interfacial electron transfer still remains challenging. Herein, Mo incorporation is employed to modulate the interfacial electronic structure of NiS/NiP, resulting in an activated electron redistribution with more electrons flowing from NiP to NiS. The enhanced electron transfer at the Mo-NiS/NiP interface further reduces its work function and positively shifts the d-band center closer to Fermi level, promoting OH and glycerol adsorption. Compared to NiS/NiP, the Mo-NiS/NiP exhibits superior electrocatalytic performance for both glycerol oxidation and hydrogen evolution reaction. In simulated alkaline seawater with glycerol, a two-electrode system using Mo-NiS/NiP as both the anode and cathode achieves a 390 mV reduction in cell voltage to reach 100 mA cm compared to water splitting, accompanied by a Faradaic efficiency above 90% for formate. This work will stimulate the further development of work function-guided design of efficient electrocatalysts for sustainable energy conversion.