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Engineering Cu+/Cu0 Interfaces With Lanthanum Doping for Efficient CO2-to-C2+ Conversion.

Jinlong Wu1, Haiqiang Mu1, Min Zhu2

  • 1College of Chemistry and Chemical Engineering, Ningxia University, Yinchuan, P. R. China.

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Summary

Lanthanum doping stabilizes crucial Cu+ sites in copper oxide catalysts, enhancing carbon dioxide conversion to valuable C2+ products. This breakthrough improves catalyst stability and efficiency for CO2 reduction.

Keywords:
CO2 electroreductionCu+ stabilizationgrain boundarylanthanum dopingmulti‐carbon products

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Area of Science:

  • Catalysis
  • Materials Science
  • Electrochemistry

Background:

  • Copper-based catalysts are promising for CO2 conversion to C2+ products.
  • Instability of active Cu+ sites hinders C-C coupling and catalyst performance.
  • Developing stable and efficient catalysts for CO2 reduction is critical.

Purpose of the Study:

  • To investigate the effect of Lanthanum (La) doping on CuₓO catalysts for CO2 reduction.
  • To understand how La doping influences Cu+ stability and C-C coupling kinetics.
  • To optimize La-doped CuₓO catalysts for enhanced C2+ selectivity and stability.

Main Methods:

  • Synthesis of Lanthanum (La)-doped CuₓO catalysts with varying La/Cu ratios.
  • Density functional theory (DFT) calculations to model electronic and structural effects.
  • In situ spectroscopic characterization to analyze catalyst behavior during CO2 reduction reaction (CO2RR).

Main Results:

  • La doping stabilizes Cu+ species by facilitating charge transfer and increasing grain boundary density.
  • Optimized La-doped CuₓO-2 catalyst achieved 45.2% C2H4 Faradaic efficiency and 75.4% C2+ FE.
  • The catalyst demonstrated exceptional stability, retaining over 90% activity after 24 hours of operation.
  • Enhanced *CO dimerization kinetics and lowered C-C coupling barriers were observed.

Conclusions:

  • Rare-earth doping, specifically La, offers a rational strategy for stabilizing active Cu+ sites in copper-based CO2 reduction catalysts.
  • La doping effectively modulates electronic properties and grain boundary structures, promoting C-C coupling and improving catalyst durability.
  • The developed La-CuₓO catalysts show significant potential for efficient and stable electrochemical CO2 conversion to valuable C2+ products.