Nature Communications (Jan 2024)

Site-selective protonation enables efficient carbon monoxide electroreduction to acetate

  • Xinyue Wang,
  • Yuanjun Chen,
  • Feng Li,
  • Rui Kai Miao,
  • Jianan Erick Huang,
  • Zilin Zhao,
  • Xiao-Yan Li,
  • Roham Dorakhan,
  • Senlin Chu,
  • Jinhong Wu,
  • Sixing Zheng,
  • Weiyan Ni,
  • Dongha Kim,
  • Sungjin Park,
  • Yongxiang Liang,
  • Adnan Ozden,
  • Pengfei Ou,
  • Yang Hou,
  • David Sinton,
  • Edward H. Sargent

DOI
https://doi.org/10.1038/s41467-024-44727-z
Journal volume & issue
Vol. 15, no. 1
pp. 1 – 10

Abstract

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Abstract Electrosynthesis of acetate from CO offers the prospect of a low-carbon-intensity route to this valuable chemical––but only once sufficient selectivity, reaction rate and stability are realized. It is a high priority to achieve the protonation of the relevant intermediates in a controlled fashion, and to achieve this while suppressing the competing hydrogen evolution reaction (HER) and while steering multicarbon (C2+) products to a single valuable product––an example of which is acetate. Here we report interface engineering to achieve solid/liquid/gas triple-phase interface regulation, and we find that it leads to site-selective protonation of intermediates and the preferential stabilization of the ketene intermediates: this, we find, leads to improved selectivity and energy efficiency toward acetate. Once we further tune the catalyst composition and also optimize for interfacial water management, we achieve a cadmium-copper catalyst that shows an acetate Faradaic efficiency (FE) of 75% with ultralow HER (<0.2% H2 FE) at 150 mA cm−2. We develop a high-pressure membrane electrode assembly system to increase CO coverage by controlling gas reactant distribution and achieve 86% acetate FE simultaneous with an acetate full-cell energy efficiency (EE) of 32%, the highest energy efficiency reported in direct acetate electrosynthesis.