Amorphous NiOn coupled with trace PtOx toward superior electrocatalytic overall water splitting in alkaline seawater media

Developing corrosion resistance bifunctional electrocatalysts with high activity and stability toward both hydrogen evolution reaction (HER) and oxygen evolution reaction (OER), especially electrolysis in seawater, is of prime significance but still pressingly challenging. Herein, in-situ introduced PtOx on the derivative amorphous NiOn is prepared via heat treatment of Ni ZIF-L nanosheets on nickel foam under low temperature (PtOx-NiOn/NF). The synthesized PtOx-NiOn/NF possesses suprahydrophilic and aerophilic surface, and then in favor of intimate contact between the electrode and electrolyte and release of the generated gas bubbles during the electrocatalysis. As a result, the in-situ PtOx-NiOn/NF electrode presents outstanding bifunctional activity, which only requires extremely low overpotentials of 32 and 240 mV to reach a current density of 10 mA center dot cm(-2) for HER and OER, respectively, which exceeds most of the electrocatalysts previously developed and even suppresses commercial Pt/C and RuO2 electrodes. As for two-electrode cell organized by PtOx-NiOn/NF, the voltages down to 1.57 and 1.58 V are necessary to drive 10 mA center dot cm(-2) with remarkable durability in 1 M KOH and alkaline seawater, respectively, along with remarkable stability. Moreover, a low cell voltage of 1.88 V is needed to achieve 1,000 mA center dot cm(-2) toward water-splitting under industrial conditions. This study provides a new idea for designing in-situ amorphous metal oxide bifunctional electrocatalyst with strong Pt-support interaction for overall water splitting.

Automated summary

In this study, corrosion-resistant bifunctional electrocatalysts with high activity and stability for seawater electrolysis were developed. PtOx-NiOn/NF electrodes were prepared by heat treatment of Ni ZIF-L nanosheets on nickel foam at low temperature. These electrodes exhibited excellent bifunctional activity with low overpotentials for both HER and OER reactions, surpassing previously developed electrocatalysts and commercial Pt/C and RuO2 electrodes. The PtOx-NiOn/NF two-electrode cell showed remarkable durability and stability in alkaline seawater. Under industrial conditions, a low cell voltage of 1.88 V was required for water-splitting at a high current density of 1000 mA/cm². This study provides a new approach in designing in-situ amorphous metal oxide bifunctional electrocatalysts with strong Pt-support interaction.