Electro-activated indigos intensify ampere-level CO2 reduction to CO on silver catalysts

Zhengyuan Li; Xing Li; Ruoyu Wang; Astrid Campos Mata; Carter S. Gerke; Shuting Xiang; Anmol Mathur; Lingyu Zhang; Dian-Zhao Lin; Tianchen Li; Krish N. Jayarapu; Andong Liu; Lavanya Gupta; Anatoly I. Frenkel; V. Sara Thoi; Pulickel M. Ajayan; Soumyabrata Roy; Yuanyue Liu; Yayuan Liu

doi:10.1038/s41467-025-58593-w

Electro-activated indigos intensify ampere-level CO₂ reduction to CO on silver catalysts

Zhengyuan Li^* (Co-first Author)
, Xing Li (Co-first Author)
, Ruoyu Wang
, Astrid Campos Mata
, Carter S. Gerke
, Shuting Xiang
, Anmol Mathur
, Lingyu Zhang
, Dian-Zhao Lin
, Tianchen Li
, Krish N. Jayarapu
, Andong Liu
, Lavanya Gupta
, Anatoly I. Frenkel
, V. Sara Thoi
, Pulickel M. Ajayan
, Soumyabrata Roy
, Yuanyue Liu
, Yayuan Liu^*

^*Corresponding author for this work

Department of Chemistry

Research output: Journal Publications and Reviews › RGC 21 - Publication in refereed journal › peer-review

26 Citations (Scopus)

67 Downloads (CityUHK Scholars)

Abstract

The electrochemical reduction of carbon dioxide (CO₂) to carbon monoxide (CO) is challenged by a selectivity decline at high current densities. Here we report a class of indigo-based molecular promoters with redox-active CO₂ binding sites to enhance the high-rate conversion of CO₂ to CO on silver (Ag) catalysts. Theoretical calculations and in situ spectroscopy analyses demonstrate that the synergistic effect at the interface of indigo-derived compounds and Ag nanoparticles could activate CO₂ molecules and accelerate the formation of key intermediates (*CO₂^– and *COOH) in the CO pathway. Indigo derivatives with electron-withdrawing groups further reduce the overpotential for CO production upon optimizing the interfacial CO₂ binding affinity. By integrating the molecular design of redox-active centres with the defect engineering of Ag structures, we achieve a Faradaic efficiency for CO exceeding 90% across a current density range of 0.10 − 1.20 A cm^–2. The Ag mass activity toward CO increases to 174 A mg^–1_Ag. This work showcases that employing redox-active CO₂ sorbents as surface modification agents is a highly effective strategy to intensify the reactivity of electrochemical CO₂ reduction. © The Author(s) 2025.

Original language	English
Article number	3206
Journal	Nature Communications
Volume	16
Online published	3 Apr 2025
DOIs	https://doi.org/10.1038/s41467-025-58593-w
Publication status	Published - 2025

Funding

We acknowledge financial support from the Johns Hopkins University, the David and Lucile Packard Foundation, the Arnold and Mabel Beckman Foundation, and the National Science Foundation (NSF grant number 2237096). This work was partially performed at the Materials Characterization and Processing Center in the Whiting School of Engineering at Johns Hopkins University. Yayuan Liu and V.S.T. are grateful for the support of the Ralph S. O\u2019Connor Sustainable Energy Institute (ROSEI). R.W. and Yuanyue Liu acknowledge the support by Welch Foundation (F-1959), and the computational resources provided by ACCESS and NREL. C.S.G and V.S.T. acknowledge the U.S. Department of Energy (DOE), Office of Science, Office of Basic Energy Sciences, Catalysis Science program, under grant DE-SC0021955. S.R. acknowledges support from IIT Kanpur (Project number 2024098) and the Chandrakanta Kesavan Center for Energy Policy and Climate Solutions, IITK (Project number 2021136H). A.C.M. would like to acknowledge CONAHCyT for the doctoral scholarship provided under the program (CVU1051087). A.I.F. and S.X. acknowledge support by the NSF grant CHE 2102299. The work carried out at Brookhaven National Laboratory was supported by the DOE under contract DE-SC0012704. XAS measurements used resource 7-BM of the National Synchrotron Light Source II, a DOE Office of Science User Facility operated for the DOE Office of Science by Brookhaven National Laboratory under contract DE-SC0012704. The 7-BM beamline operations were supported in part by the Synchrotron Catalysis Consortium (DOE Office of Basic Energy Sciences grant DE-SC0012335). We appreciate beamline support by L. Ma, D. Yang and A. Tayal. Z.L. would like to thank T. Zhang and X. She for their valuable suggestions.

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 13 Climate Action

Publisher's Copyright Statement

This full text is made available under CC-BY-NC-ND 4.0. https://creativecommons.org/licenses/by-nc-nd/4.0/

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Li, Z., Li, X., Wang, R., Campos Mata, A., Gerke, C. S., Xiang, S., Mathur, A., Zhang, L., Lin, D.-Z., Li, T., Jayarapu, K. N., Liu, A., Gupta, L., Frenkel, A. I., Thoi, V. S., Ajayan, P. M., Roy, S., Liu, Y., & Liu, Y. (2025). Electro-activated indigos intensify ampere-level CO₂ reduction to CO on silver catalysts. Nature Communications, 16, Article 3206. https://doi.org/10.1038/s41467-025-58593-w

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title = "Electro-activated indigos intensify ampere-level CO2 reduction to CO on silver catalysts",

abstract = "The electrochemical reduction of carbon dioxide (CO2) to carbon monoxide (CO) is challenged by a selectivity decline at high current densities. Here we report a class of indigo-based molecular promoters with redox-active CO2 binding sites to enhance the high-rate conversion of CO2 to CO on silver (Ag) catalysts. Theoretical calculations and in situ spectroscopy analyses demonstrate that the synergistic effect at the interface of indigo-derived compounds and Ag nanoparticles could activate CO2 molecules and accelerate the formation of key intermediates (*CO2– and *COOH) in the CO pathway. Indigo derivatives with electron-withdrawing groups further reduce the overpotential for CO production upon optimizing the interfacial CO2 binding affinity. By integrating the molecular design of redox-active centres with the defect engineering of Ag structures, we achieve a Faradaic efficiency for CO exceeding 90\% across a current density range of 0.10 − 1.20 A cm–2. The Ag mass activity toward CO increases to 174 A mg–1Ag. This work showcases that employing redox-active CO2 sorbents as surface modification agents is a highly effective strategy to intensify the reactivity of electrochemical CO2 reduction. {\textcopyright} The Author(s) 2025.",

author = "Zhengyuan Li and Xing Li and Ruoyu Wang and \{Campos Mata\}, Astrid and Gerke, \{Carter S.\} and Shuting Xiang and Anmol Mathur and Lingyu Zhang and Dian-Zhao Lin and Tianchen Li and Jayarapu, \{Krish N.\} and Andong Liu and Lavanya Gupta and Frenkel, \{Anatoly I.\} and Thoi, \{V. Sara\} and Ajayan, \{Pulickel M.\} and Soumyabrata Roy and Yuanyue Liu and Yayuan Liu",

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AU - Campos Mata, Astrid

AU - Gerke, Carter S.

AU - Xiang, Shuting

AU - Mathur, Anmol

AU - Zhang, Lingyu

AU - Lin, Dian-Zhao

AU - Li, Tianchen

AU - Jayarapu, Krish N.

AU - Liu, Andong

AU - Gupta, Lavanya

AU - Frenkel, Anatoly I.

AU - Thoi, V. Sara

AU - Ajayan, Pulickel M.

AU - Roy, Soumyabrata

AU - Liu, Yuanyue

AU - Liu, Yayuan

PY - 2025

Y1 - 2025

N2 - The electrochemical reduction of carbon dioxide (CO2) to carbon monoxide (CO) is challenged by a selectivity decline at high current densities. Here we report a class of indigo-based molecular promoters with redox-active CO2 binding sites to enhance the high-rate conversion of CO2 to CO on silver (Ag) catalysts. Theoretical calculations and in situ spectroscopy analyses demonstrate that the synergistic effect at the interface of indigo-derived compounds and Ag nanoparticles could activate CO2 molecules and accelerate the formation of key intermediates (*CO2– and *COOH) in the CO pathway. Indigo derivatives with electron-withdrawing groups further reduce the overpotential for CO production upon optimizing the interfacial CO2 binding affinity. By integrating the molecular design of redox-active centres with the defect engineering of Ag structures, we achieve a Faradaic efficiency for CO exceeding 90% across a current density range of 0.10 − 1.20 A cm–2. The Ag mass activity toward CO increases to 174 A mg–1Ag. This work showcases that employing redox-active CO2 sorbents as surface modification agents is a highly effective strategy to intensify the reactivity of electrochemical CO2 reduction. © The Author(s) 2025.

AB - The electrochemical reduction of carbon dioxide (CO2) to carbon monoxide (CO) is challenged by a selectivity decline at high current densities. Here we report a class of indigo-based molecular promoters with redox-active CO2 binding sites to enhance the high-rate conversion of CO2 to CO on silver (Ag) catalysts. Theoretical calculations and in situ spectroscopy analyses demonstrate that the synergistic effect at the interface of indigo-derived compounds and Ag nanoparticles could activate CO2 molecules and accelerate the formation of key intermediates (*CO2– and *COOH) in the CO pathway. Indigo derivatives with electron-withdrawing groups further reduce the overpotential for CO production upon optimizing the interfacial CO2 binding affinity. By integrating the molecular design of redox-active centres with the defect engineering of Ag structures, we achieve a Faradaic efficiency for CO exceeding 90% across a current density range of 0.10 − 1.20 A cm–2. The Ag mass activity toward CO increases to 174 A mg–1Ag. This work showcases that employing redox-active CO2 sorbents as surface modification agents is a highly effective strategy to intensify the reactivity of electrochemical CO2 reduction. © The Author(s) 2025.

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