Abstract
Simple, large-scale synthesis of metal single-atom catalysts (SACs) is limited by the aggregation of metal atoms on the support material surface. The N atoms in small organic ligands (SOLs) can anchor single metal atoms, affording abundant surface-active sites. In this study, we investigated the effect of the nitrogen/carbon ratio (N/C) in SOLs on the properties of the resultant Ni single-atom confined nitrogen-doped carbon black (Ni-NCB). The N/C ratio affected the thermal stability of Ni-NCB_N/Cs during carbonization, and the optimal Ni-NCB (Ni-NCB_0.5) was synthesized with the SOL 2-methylimidazole. Ni-NCB_0.5 achieved a CO partial current density of > 500 mA cm–2 and high CO Faradaic efficiency (96.4 %) in the CO2 reduction reaction. The 3- and 4-cell stack systems with Ni-NCB_0.5 (25 cm2 area per unit cell) exhibited an overall current of 10 A, high CO selectivity (> 96.0 %), and long-term stability (50 h). This synthetic strategy for SACs can be commercialized and even extended to other industrial electrocatalysts.
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