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A rigorous electrochemical ammonia synthesis protocol with quantitative isotope measurements

Author

Listed:
  • Suzanne Z. Andersen

    (Technical University of Denmark)

  • Viktor Čolić

    (Technical University of Denmark)

  • Sungeun Yang

    (Technical University of Denmark
    Korea Institute of Science and Technology (KIST))

  • Jay A. Schwalbe

    (Stanford University)

  • Adam C. Nielander

    (Stanford University)

  • Joshua M. McEnaney

    (Stanford University)

  • Kasper Enemark-Rasmussen

    (Technical University of Denmark)

  • Jon G. Baker

    (Stanford University)

  • Aayush R. Singh

    (Stanford University)

  • Brian A. Rohr

    (Stanford University)

  • Michael J. Statt

    (Stanford University)

  • Sarah J. Blair

    (Stanford University)

  • Stefano Mezzavilla

    (Imperial College London)

  • Jakob Kibsgaard

    (Technical University of Denmark)

  • Peter C. K. Vesborg

    (Technical University of Denmark)

  • Matteo Cargnello

    (Stanford University)

  • Stacey F. Bent

    (Stanford University)

  • Thomas F. Jaramillo

    (Stanford University)

  • Ifan E. L. Stephens

    (Imperial College London)

  • Jens K. Nørskov

    (Stanford University)

  • Ib Chorkendorff

    (Technical University of Denmark)

Abstract

The electrochemical synthesis of ammonia from nitrogen under mild conditions using renewable electricity is an attractive alternative1–4 to the energy-intensive Haber–Bosch process, which dominates industrial ammonia production. However, there are considerable scientific and technical challenges5,6 facing the electrochemical alternative, and most experimental studies reported so far have achieved only low selectivities and conversions. The amount of ammonia produced is usually so small that it cannot be firmly attributed to electrochemical nitrogen fixation7–9 rather than contamination from ammonia that is either present in air, human breath or ion-conducting membranes9, or generated from labile nitrogen-containing compounds (for example, nitrates, amines, nitrites and nitrogen oxides) that are typically present in the nitrogen gas stream10, in the atmosphere or even in the catalyst itself. Although these sources of experimental artefacts are beginning to be recognized and managed11,12, concerted efforts to develop effective electrochemical nitrogen reduction processes would benefit from benchmarking protocols for the reaction and from a standardized set of control experiments designed to identify and then eliminate or quantify the sources of contamination. Here we propose a rigorous procedure using 15N2 that enables us to reliably detect and quantify the electrochemical reduction of nitrogen to ammonia. We demonstrate experimentally the importance of various sources of contamination, and show how to remove labile nitrogen-containing compounds from the nitrogen gas as well as how to perform quantitative isotope measurements with cycling of 15N2 gas to reduce both contamination and the cost of isotope measurements. Following this protocol, we find that no ammonia is produced when using the most promising pure-metal catalysts for this reaction in aqueous media, and we successfully confirm and quantify ammonia synthesis using lithium electrodeposition in tetrahydrofuran13. The use of this rigorous protocol should help to prevent false positives from appearing in the literature, thus enabling the field to focus on viable pathways towards the practical electrochemical reduction of nitrogen to ammonia.

Suggested Citation

  • Suzanne Z. Andersen & Viktor Čolić & Sungeun Yang & Jay A. Schwalbe & Adam C. Nielander & Joshua M. McEnaney & Kasper Enemark-Rasmussen & Jon G. Baker & Aayush R. Singh & Brian A. Rohr & Michael J. St, 2019. "A rigorous electrochemical ammonia synthesis protocol with quantitative isotope measurements," Nature, Nature, vol. 570(7762), pages 504-508, June.
  • Handle: RePEc:nat:nature:v:570:y:2019:i:7762:d:10.1038_s41586-019-1260-x
    DOI: 10.1038/s41586-019-1260-x
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    Citations

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    Cited by:

    1. Po-Wei Huang & Marta C. Hatzell, 2022. "Prospects and good experimental practices for photocatalytic ammonia synthesis," Nature Communications, Nature, vol. 13(1), pages 1-7, December.
    2. Paul A. Kempler & Adam C. Nielander, 2023. "Reliable reporting of Faradaic efficiencies for electrocatalysis research," Nature Communications, Nature, vol. 14(1), pages 1-4, December.
    3. Jia-Yi Fang & Qi-Zheng Zheng & Yao-Yin Lou & Kuang-Min Zhao & Sheng-Nan Hu & Guang Li & Ouardia Akdim & Xiao-Yang Huang & Shi-Gang Sun, 2022. "Ampere-level current density ammonia electrochemical synthesis using CuCo nanosheets simulating nitrite reductase bifunctional nature," Nature Communications, Nature, vol. 13(1), pages 1-13, December.
    4. Cheng Du & Joel P. Mills & Asfaw G. Yohannes & Wei Wei & Lei Wang & Siyan Lu & Jian-Xiang Lian & Maoyu Wang & Tao Guo & Xiyang Wang & Hua Zhou & Cheng-Jun Sun & John Z. Wen & Brian Kendall & Martin Co, 2023. "Cascade electrocatalysis via AgCu single-atom alloy and Ag nanoparticles in CO2 electroreduction toward multicarbon products," Nature Communications, Nature, vol. 14(1), pages 1-10, December.
    5. Doris Segets & Corina Andronescu & Ulf-Peter Apfel, 2023. "Accelerating CO2 electrochemical conversion towards industrial implementation," Nature Communications, Nature, vol. 14(1), pages 1-5, December.
    6. Huize Wang & Ranga Rohit Seemakurthi & Gao-Feng Chen & Volker Strauss & Oleksandr Savateev & Guangtong Hai & Liangxin Ding & Núria López & Haihui Wang & Markus Antonietti, 2023. "Laser-induced nitrogen fixation," Nature Communications, Nature, vol. 14(1), pages 1-7, December.
    7. Xianbiao Fu & Aoni Xu & Jakob B. Pedersen & Shaofeng Li & Rokas Sažinas & Yuanyuan Zhou & Suzanne Z. Andersen & Mattia Saccoccio & Niklas H. Deissler & Jon Bjarke Valbæk Mygind & Jakob Kibsgaard & Pet, 2024. "Phenol as proton shuttle and buffer for lithium-mediated ammonia electrosynthesis," Nature Communications, Nature, vol. 15(1), pages 1-11, December.
    8. Rao, Xufeng & Liu, Minmin & Chien, Meifang & Inoue, Chihiro & Zhang, Jiujun & Liu, Yuyu, 2022. "Recent progress in noble metal electrocatalysts for nitrogen-to-ammonia conversion," Renewable and Sustainable Energy Reviews, Elsevier, vol. 168(C).
    9. Jiabao Lv & Ang Cao & Yunhao Zhong & Qingyang Lin & Xiaodong Li & Hao Bin Wu & Jianhua Yan & Angjian Wu, 2024. "Promoting the OH cycle on an activated dynamic interface for electrocatalytic ammonia synthesis," Nature Communications, Nature, vol. 15(1), pages 1-10, December.
    10. Xu, Haiyang & Zhang, Le & Wei, ShengJie & Tong, Xuan & Yang, Yue & Ji, Xu, 2024. "A novel solar system for photothermal-assisted electrocatalytic nitrate reduction reaction to ammonia," Renewable Energy, Elsevier, vol. 221(C).
    11. Jong-Hoon Kim & Tian-Yi Dai & Mihyun Yang & Jeong-Min Seo & Jae Seong Lee & Do Hyung Kweon & Xing-You Lang & Kyuwook Ihm & Tae Joo Shin & Gao-Feng Han & Qing Jiang & Jong-Beom Baek, 2023. "Achieving volatile potassium promoted ammonia synthesis via mechanochemistry," Nature Communications, Nature, vol. 14(1), pages 1-9, December.

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