Enhanced *COOH Adsorption over Edge-Rich Ni–N<sub>4</sub> Sites for Efficient Acidic CO<sub>2</sub> Electroreduction
Ziwen Mei, Yingjie He, Kang Liu, Wenjie Luo, Yao Tan, Qin Chen, Haiying Wang, Xiaoxi Guo, Qing Wu, Chao Ma, Junwei Fu, Zhang Lin, Min Liu
Abstract
Single-atom Ni catalysts hold great promise for the acidic CO 2 reduction reaction (CO 2 RR), owing to their high CO selectivity. However, their performance under industrially relevant high current conditions is limited by the weak interaction between isolated Ni–N 4 sites and *COOH intermediates, restricting efficient CO 2 conversion. Here, we introduced edge-rich Ni–N 4 sites via support vacancy engineering to enhance *COOH adsorption, thereby boosting the CO 2 RR activity and selectivity in acidic media. Density functional theory calculations revealed that edge-rich Ni–N 4 sites induced an upward shift in the Ni d -band center, leading to stronger *COOH binding and improved reaction kinetics. Aberration-corrected high-angle annular dark-field scanning transmission electron microscopy images confirmed the uniform dispersion of single-atom Ni sites at the edge of the carbon support. X-ray adsorption spectroscopy further validated the successful anchoring of Ni–N 4 sites on the carbon nanotube matrix. Furthermore, in situ attenuated total reflection surface-enhanced infrared absorption spectroscopy directly evidenced the enhanced *COOH binding on the engineered active sites. As a result, the optimized catalyst achieved a high CO faradaic efficiency exceeding 94.5% at 800 mA cm –2, alongside a cathodic energy efficiency above 44.2% at pH = 1, suppressing previously reported benchmarks. This work establishes a versatile strategy for electronic structure modulation through edge-site engineering, offering a pathway to unlock the full potential of single-atom catalysts for the acidic CO 2 RR at high current densities.