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Dynamic (Sub)surface-Oxygen Enables Highly Efficient Carbonyl-Coupling for Electrochemical Carbon Dioxide Reduction.

You-Chiuan ChuKuan-Hsu ChenChing-Wei TungHsiao-Chien ChenJiali WangTsung-Rong KuoChia-Shuo HsuKuo-Hsin LinLi Duan TsaiHsiao-Chien Chen
Published in: Advanced materials (Deerfield Beach, Fla.) (2024)
Nowadays high-valent Cu species (i.e., Cu δ+ ) has been clarified to enhance multi-carbon production in electrochemical CO 2 reduction reaction (CO 2 RR). Nonetheless, the inconsistent average Cu valence states have been reported to significantly govern the product profile of CO 2 RR, which may lead to misunderstanding of the enhanced mechanism for multi-carbon production and results in an ambiguous roles of high-valent Cu species. Dynamic Cu δ+ during CO 2 RR leads to erratic valence states and challenges of high-valent species determination. Herein, we propose an alternative descriptor of (sub)surface oxygen, the (sub)surface-oxygenated degree (κ) to quantify the active high-valent Cu species on the (sub)surface, which regulates the multi-carbon production of CO 2 RR. The κ validates a strong correlation to the carbonyl (*CO) coupling efficiency and is the critical factor for the multi-carbon enhancement, in which an optimized Cu 2 O@Pd 2.31 achieves the multi-carbon partial current density of ∼330 mA cm -2 with a faradaic efficiency of 83.5%. This work shows a promising way to unveil the role of high-valent species and further achieve carbon neutralization. This article is protected by copyright. All rights reserved.
Keyphrases
  • highly efficient
  • aqueous solution
  • metal organic framework
  • carbon dioxide
  • gold nanoparticles
  • molecularly imprinted
  • high resolution