Unraveling Mechanistic Reaction Pathways of the Electrochemical CO2 Reduction on Fe-N-C Single-Site Catalysts

Wen Ju; Alexander Bagger; Xingli Wang; Yulin Tsai; Fang Luo; Tim Moeller; Huan Wang; Jan Rossmeisl; Ana Sofia Varela; Peter Strasser

doi:10.1021/acsenergylett.9b01049

Unraveling Mechanistic Reaction Pathways of the Electrochemical CO2 Reduction on Fe-N-C Single-Site Catalysts

Wen Ju, Alexander Bagger, Xingli Wang, Yulin Tsai, Fang Luo, Tim Moeller, Huan Wang, Jan Rossmeisl, Ana Sofia Varela, Peter Strasser

Department of Chemistry

51 Citations (Scopus)

Abstract

We report a joint experimental-computational mechanistic study of electrochemical reduction of CO₂ to CH₄, catalyzed by solid-state Fe-N-C catalysts, which feature atomically dispersed, catalytically active Fe-N_x sites and represent one of the very rare examples of solid, non-Cu-based electrocatalysts that yield hydrocarbon products. Work reported here focuses on the identification of plausible mechanistic pathways from CO₂ to various C₁ products including methane. It is found that Fe-N_x sites convert only CO₂, CO, and CH₂O into methane, whereas CH₃OH appears to be an end product. Distinctly different pH dependence of the catalytic CH₄ evolution from CH₂O in comparison with that of CO₂ and CO reduction indicates differences in the proton participation of rate-determining steps. By comparing the experimental observations with density functional theory derived free energy diagrams of reactive intermediates along the CO₂ reduction reaction coordinates, we unravel the dominant mechanistic pathways and roles of CO and CH₂O during the catalytic CO₂-to-CH₄ cascades and their rate-determining steps. We close with a comprehensive reaction network of CO₂RR on single-site Fe-N-C catalysts, which may prove useful in developing efficient, non-Cu-based catalysts for hydrocarbon production.

Original language	English
Journal	ACS Energy Letters
Volume	4
Issue number	7
Pages (from-to)	1663-1671
ISSN	2380-8195
DOIs	https://doi.org/10.1021/acsenergylett.9b01049
Publication status	Published - 12 Jul 2019

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title = "Unraveling Mechanistic Reaction Pathways of the Electrochemical CO2 Reduction on Fe-N-C Single-Site Catalysts",

abstract = "We report a joint experimental-computational mechanistic study of electrochemical reduction of CO2 to CH4, catalyzed by solid-state Fe-N-C catalysts, which feature atomically dispersed, catalytically active Fe-Nx sites and represent one of the very rare examples of solid, non-Cu-based electrocatalysts that yield hydrocarbon products. Work reported here focuses on the identification of plausible mechanistic pathways from CO2 to various C1 products including methane. It is found that Fe-Nx sites convert only CO2, CO, and CH2O into methane, whereas CH3OH appears to be an end product. Distinctly different pH dependence of the catalytic CH4 evolution from CH2O in comparison with that of CO2 and CO reduction indicates differences in the proton participation of rate-determining steps. By comparing the experimental observations with density functional theory derived free energy diagrams of reactive intermediates along the CO2 reduction reaction coordinates, we unravel the dominant mechanistic pathways and roles of CO and CH2O during the catalytic CO2-to-CH4 cascades and their rate-determining steps. We close with a comprehensive reaction network of CO2RR on single-site Fe-N-C catalysts, which may prove useful in developing efficient, non-Cu-based catalysts for hydrocarbon production.",

author = "Wen Ju and Alexander Bagger and Xingli Wang and Yulin Tsai and Fang Luo and Tim Moeller and Huan Wang and Jan Rossmeisl and {Sofia Varela}, Ana and Peter Strasser",

year = "2019",

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day = "12",

doi = "10.1021/acsenergylett.9b01049",

language = "English",

volume = "4",

pages = "1663--1671",

journal = "ACS Energy Letters",

issn = "2380-8195",

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TY - JOUR

T1 - Unraveling Mechanistic Reaction Pathways of the Electrochemical CO2 Reduction on Fe-N-C Single-Site Catalysts

AU - Ju, Wen

AU - Bagger, Alexander

AU - Wang, Xingli

AU - Tsai, Yulin

AU - Luo, Fang

AU - Moeller, Tim

AU - Wang, Huan

AU - Rossmeisl, Jan

AU - Sofia Varela, Ana

AU - Strasser, Peter

PY - 2019/7/12

Y1 - 2019/7/12

N2 - We report a joint experimental-computational mechanistic study of electrochemical reduction of CO2 to CH4, catalyzed by solid-state Fe-N-C catalysts, which feature atomically dispersed, catalytically active Fe-Nx sites and represent one of the very rare examples of solid, non-Cu-based electrocatalysts that yield hydrocarbon products. Work reported here focuses on the identification of plausible mechanistic pathways from CO2 to various C1 products including methane. It is found that Fe-Nx sites convert only CO2, CO, and CH2O into methane, whereas CH3OH appears to be an end product. Distinctly different pH dependence of the catalytic CH4 evolution from CH2O in comparison with that of CO2 and CO reduction indicates differences in the proton participation of rate-determining steps. By comparing the experimental observations with density functional theory derived free energy diagrams of reactive intermediates along the CO2 reduction reaction coordinates, we unravel the dominant mechanistic pathways and roles of CO and CH2O during the catalytic CO2-to-CH4 cascades and their rate-determining steps. We close with a comprehensive reaction network of CO2RR on single-site Fe-N-C catalysts, which may prove useful in developing efficient, non-Cu-based catalysts for hydrocarbon production.

AB - We report a joint experimental-computational mechanistic study of electrochemical reduction of CO2 to CH4, catalyzed by solid-state Fe-N-C catalysts, which feature atomically dispersed, catalytically active Fe-Nx sites and represent one of the very rare examples of solid, non-Cu-based electrocatalysts that yield hydrocarbon products. Work reported here focuses on the identification of plausible mechanistic pathways from CO2 to various C1 products including methane. It is found that Fe-Nx sites convert only CO2, CO, and CH2O into methane, whereas CH3OH appears to be an end product. Distinctly different pH dependence of the catalytic CH4 evolution from CH2O in comparison with that of CO2 and CO reduction indicates differences in the proton participation of rate-determining steps. By comparing the experimental observations with density functional theory derived free energy diagrams of reactive intermediates along the CO2 reduction reaction coordinates, we unravel the dominant mechanistic pathways and roles of CO and CH2O during the catalytic CO2-to-CH4 cascades and their rate-determining steps. We close with a comprehensive reaction network of CO2RR on single-site Fe-N-C catalysts, which may prove useful in developing efficient, non-Cu-based catalysts for hydrocarbon production.

U2 - 10.1021/acsenergylett.9b01049

DO - 10.1021/acsenergylett.9b01049

M3 - Letter

SN - 2380-8195

VL - 4

SP - 1663

EP - 1671

JO - ACS Energy Letters

JF - ACS Energy Letters

IS - 7

ER -

Unraveling Mechanistic Reaction Pathways of the Electrochemical CO2 Reduction on Fe-N-C Single-Site Catalysts

Abstract

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