Electrochemical water splitting is a promising method for the generation of "green hydrogen", a renewable and sustainable energy source. However, the complex, multistep synthesis processes, often involving hazardous or expensive chemicals, limit its broader adoption. Herein, a nitrate (NO) anion-intercalated nickel-iron-cerium mixed-metal (oxy)hydroxide heterostructure electrocatalyst is fabricated on nickel foam (NiFeCeOH@NF) via a simple electrodeposition method followed by cyclic voltammetry activation to enhance its surface properties. The NiFeCeOH@NF electrocatalyst exhibited a low overpotential of 72 and 186 mV at 10 mA cm for the hydrogen evolution reaction (HER) and oxygen evolution reaction (OER), respectively, in 1.0 M KOH. In a two-electrode system, the NiFeCeOH@NF obtained a low voltage of 1.47 V at 10 mA cm in 1.0 M KOH with robust stability. Results revealed that the notable activity of the NiFeCeOH@NF catalyst is primarily due to (i) hierarchical nanosheet morphology, which provides a large surface area and abundant active sites; (ii) NO anion intercalation enhances electrode stability and eliminates the need for binders while simultaneously promoting a strong catalyst-substrate adhesion, resulting in decreased electrode resistance and accelerated reaction kinetics; and (iii) the unique superhydrophilic surface properties facilitate electrolyte penetration through capillary action and minimize gas bubble formation by reducing interfacial tension.
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Article Synopsis
- The study focuses on creating cost-effective and stable electrocatalysts made from nonprecious metals for efficient water splitting to produce renewable hydrogen.
- It discusses the synthesis of transition metal oxyhydroxides and nitrides with varied shapes, specifically highlighting Fe-doped Co-MOF, which enhances oxygen evolution reaction (OER) performance.
- The findings show that using Co(Fe)OOH as the anode and Co/MoN as the cathode in an alkaline electrolyzer leads to a low cell voltage of 1.49 V with impressive long-term stability of 100 hours.
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