Facile and scalable synthesis of 2D porous Ni/C via a salt-template assisted approach for enhanced urea oxidation reaction and energy-saving hydrogen production

Urea splitting has gained increasing attention for energy-saving hydrogen production. The development of inexpensive, efficient and durable nanostructured electrocatalysts is highly desired to overcome the sluggish kinetics of the urea oxidation reaction (UOR). Nickel-containing materials have emerged as inexpensive and promising electrocatalysts for UOR in recent years. Herein, a series of cost-effective composites consisting of different loadings of Ni nanoparticles anchored on two-dimensional (2D) porous carbon nanosheets (denoted as Ni/CS) were fabricated for UOR via a facile and eco-friendly salt template-assisted approach. Among the prepared Ni/CS composites, the 4-Ni/CS sample with a suitable nickel loading and optimum structures exhibited the best UOR performances with a low potential of 1.369 V vs. reversible hydrogen electrode (RHE) at the current density of 10 mA cm(-2) and a low Tafel slope of 39 mV dec(-1). Furthermore, an overall urea splitting cell with the optimized 4-Ni/CS as the anode catalyst delivered only 1.372 V at 10 mA cm(-2), which was 200 mV lower than the pure water splitting cell. The enhanced performances of 4-Ni/CS for UOR and the urea splitting cell were mainly attributed to its larger electrocatalytic specific area, more abundant active sites and defects, and faster mass transfer. The remarkable 2D porous 4-Ni/CS electrocatalyst exhibits potential application in UOR and energy-saving hydrogen production.

Automated summary

Urea splitting for hydrogen production has attracted attention for energy-saving purposes. This study developed cost-effective composites of Ni nanoparticles anchored on 2D porous carbon nanosheets, which exhibited excellent urea oxidation reaction (UOR) performance. The optimized 4-Ni/CS catalyst showed low potential and Tafel slope, and the overall urea splitting cell with 4-Ni/CS as the anode catalyst achieved significant voltage reduction compared to pure water splitting. The enhanced performance of 4-Ni/CS was attributed to its larger specific area, abundant active sites, defects, and faster mass transfer.