Nature Communications (Sep 2024)

Reactive capture of CO2 via amino acid

  • Yurou Celine Xiao,
  • Siyu Sonia Sun,
  • Yong Zhao,
  • Rui Kai Miao,
  • Mengyang Fan,
  • Geonhui Lee,
  • Yuanjun Chen,
  • Christine M. Gabardo,
  • Yan Yu,
  • Chenyue Qiu,
  • Zunmin Guo,
  • Xinyue Wang,
  • Panagiotis Papangelakis,
  • Jianan Erick Huang,
  • Feng Li,
  • Colin P. O’Brien,
  • Jiheon Kim,
  • Kai Han,
  • Paul J. Corbett,
  • Jane Y. Howe,
  • Edward H. Sargent,
  • David Sinton

DOI
https://doi.org/10.1038/s41467-024-51908-3
Journal volume & issue
Vol. 15, no. 1
pp. 1 – 10

Abstract

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Abstract Reactive capture of carbon dioxide (CO2) offers an electrified pathway to produce renewable carbon monoxide (CO), which can then be upgraded into long-chain hydrocarbons and fuels. Previous reactive capture systems relied on hydroxide- or amine-based capture solutions. However, selectivity for CO remains low (<50%) for hydroxide-based systems and conventional amines are prone to oxygen (O2) degradation. Here, we develop a reactive capture strategy using potassium glycinate (K-GLY), an amino acid salt (AAS) capture solution applicable to O2-rich CO2-lean conditions. By employing a single-atom catalyst, engineering the capture solution, and elevating the operating temperature and pressure, we increase the availability of dissolved in-situ CO2 and achieve CO production with 64% Faradaic efficiency (FE) at 50 mA cm−2. We report a measured CO energy efficiency (EE) of 31% and an energy intensity of 40 GJ tCO −1, exceeding the best hydroxide- and amine-based reactive capture reports. The feasibility of the full reactive capture process is demonstrated with both simulated flue gas and direct air input.