Nature Communications (Apr 2024)

Molecular tuning boosts asymmetric C-C coupling for CO conversion to acetate

  • Jie Ding,
  • Fuhua Li,
  • Xinyi Ren,
  • Yuhang Liu,
  • Yifan Li,
  • Zheng Shen,
  • Tian Wang,
  • Weijue Wang,
  • Yang-Gang Wang,
  • Yi Cui,
  • Hongbin Yang,
  • Tianyu Zhang,
  • Bin Liu

DOI
https://doi.org/10.1038/s41467-024-47913-1
Journal volume & issue
Vol. 15, no. 1
pp. 1 – 9

Abstract

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Abstract Electrochemical carbon dioxide/carbon monoxide reduction reaction offers a promising route to synthesize fuels and value-added chemicals, unfortunately their activities and selectivities remain unsatisfactory. Here, we present a general surface molecular tuning strategy by modifying Cu2O with a molecular pyridine-derivative. The surface modified Cu2O nanocubes by 4-mercaptopyridine display a high Faradaic efficiency of greater than 60% in electrochemical carbon monoxide reduction reaction to acetate with a current density as large as 380 mA/cm2 in a liquid electrolyte flow cell. In-situ attenuated total reflectance surface-enhanced infrared absorption spectroscopy reveals stronger *CO signal with bridge configuration and stronger *OCCHO signal over modified Cu2O nanocubes by 4-mercaptopyridine than unmodified Cu2O nanocubes during electrochemical CO reduction. Density function theory calculations disclose that local molecular tuning can effectively regulate the electronic structure of copper catalyst, enhancing *CO and *CHO intermediates adsorption by the stabilization effect through hydrogen bonding, which can greatly promote asymmetric *CO-*CHO coupling in electrochemical carbon monoxide reduction reaction.