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Highly durable, coking and sulfur tolerant, fuel-flexible protonic ceramic fuel cells

Author

Listed:
  • Chuancheng Duan

    (Colorado School of Mines)

  • Robert J. Kee

    (Colorado School of Mines)

  • Huayang Zhu

    (Colorado School of Mines)

  • Canan Karakaya

    (Colorado School of Mines)

  • Yachao Chen

    (Colorado School of Mines)

  • Sandrine Ricote

    (Colorado School of Mines)

  • Angelique Jarry

    (University of Maryland)

  • Ethan J. Crumlin

    (Lawrence Berkeley National Laboratory)

  • David Hook

    (CoorsTek)

  • Robert Braun

    (Colorado School of Mines)

  • Neal P. Sullivan

    (Colorado School of Mines)

  • Ryan O’Hayre

    (Colorado School of Mines)

Abstract

Protonic ceramic fuel cells, like their higher-temperature solid-oxide fuel cell counterparts, can directly use both hydrogen and hydrocarbon fuels to produce electricity at potentially more than 50 per cent efficiency1,2. Most previous direct-hydrocarbon fuel cell research has focused on solid-oxide fuel cells based on oxygen-ion-conducting electrolytes, but carbon deposition (coking) and sulfur poisoning typically occur when such fuel cells are directly operated on hydrocarbon- and/or sulfur-containing fuels, resulting in severe performance degradation over time3–6. Despite studies suggesting good performance and anti-coking resistance in hydrocarbon-fuelled protonic ceramic fuel cells2,7,8, there have been no systematic studies of long-term durability. Here we present results from long-term testing of protonic ceramic fuel cells using a total of 11 different fuels (hydrogen, methane, domestic natural gas (with and without hydrogen sulfide), propane, n-butane, i-butane, iso-octane, methanol, ethanol and ammonia) at temperatures between 500 and 600 degrees Celsius. Several cells have been tested for over 6,000 hours, and we demonstrate excellent performance and exceptional durability (less than 1.5 per cent degradation per 1,000 hours in most cases) across all fuels without any modifications in the cell composition or architecture. Large fluctuations in temperature are tolerated, and coking is not observed even after thousands of hours of continuous operation. Finally, sulfur, a notorious poison for both low-temperature and high-temperature fuel cells, does not seem to affect the performance of protonic ceramic fuel cells when supplied at levels consistent with commercial fuels. The fuel flexibility and long-term durability demonstrated by the protonic ceramic fuel cell devices highlight the promise of this technology and its potential for commercial application.

Suggested Citation

  • Chuancheng Duan & Robert J. Kee & Huayang Zhu & Canan Karakaya & Yachao Chen & Sandrine Ricote & Angelique Jarry & Ethan J. Crumlin & David Hook & Robert Braun & Neal P. Sullivan & Ryan O’Hayre, 2018. "Highly durable, coking and sulfur tolerant, fuel-flexible protonic ceramic fuel cells," Nature, Nature, vol. 557(7704), pages 217-222, May.
  • Handle: RePEc:nat:nature:v:557:y:2018:i:7704:d:10.1038_s41586-018-0082-6
    DOI: 10.1038/s41586-018-0082-6
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    Cited by:

    1. Chang, Wanhyuk & Kang, Eun Heui & Jeong, Heon Jun & Choi, Wonjoon & Shim, Joon Hyung, 2023. "Inkjet printing of perovskite ceramics for high-performance proton ceramic fuel cells," Energy, Elsevier, vol. 268(C).
    2. Fan Liu & Chuancheng Duan, 2021. "Direct-Hydrocarbon Proton-Conducting Solid Oxide Fuel Cells," Sustainability, MDPI, vol. 13(9), pages 1-9, April.
    3. Pan, Zehua & Shen, Jian & Wang, Jingyi & Xu, Xinhai & Chan, Wei Ping & Liu, Siyu & Zhou, Yexin & Yan, Zilin & Jiao, Zhenjun & Lim, Teik-Thye & Zhong, Zheng, 2022. "Thermodynamic analyses of a standalone diesel-fueled distributed power generation system based on solid oxide fuel cells," Applied Energy, Elsevier, vol. 308(C).
    4. Thieu, Cam-Anh & Ji, Ho-Il & Kim, Hyoungchul & Yoon, Kyung Joong & Lee, Jong-Ho & Son, Ji-Won, 2019. "Palladium incorporation at the anode of thin-film solid oxide fuel cells and its effect on direct utilization of butane fuel at 600 °C," Applied Energy, Elsevier, vol. 243(C), pages 155-164.
    5. Christos Drosakis & Savvas Douvartzides & Costas Athanasiou & Georgios Skodras, 2024. "Recent Progress on the Materials of Oxygen Ion-Conducting Solid Oxide Fuel Cells and Experimental Analysis of Biogas-Assisted Electrolysis over a LSC Anode," Energies, MDPI, vol. 17(22), pages 1-26, November.
    6. Kim, J. & Sengodan, S. & Kim, S. & Kwon, O. & Bu, Y. & Kim, G., 2019. "Proton conducting oxides: A review of materials and applications for renewable energy conversion and storage," Renewable and Sustainable Energy Reviews, Elsevier, vol. 109(C), pages 606-618.
    7. Lv, Xiuqing & Chen, Huili & Zhou, Wei & Cheng, Fangqin & Li, Si-Dian & Shao, Zongping, 2020. "Direct-methane solid oxide fuel cells with an in situ formed Ni–Fe alloy composite catalyst layer over Ni–YSZ anodes," Renewable Energy, Elsevier, vol. 150(C), pages 334-341.
    8. Mohamad Fairus Rabuni & Tao Li & Mohd Hafiz Dzarfan Othman & Faidzul Hakim Adnan & Kang Li, 2023. "Progress in Solid Oxide Fuel Cells with Hydrocarbon Fuels," Energies, MDPI, vol. 16(17), pages 1-36, September.
    9. Hu, Enyi & Wang, Faze & Yousaf, Muhammad & Wang, Jun & Lund, Peter & Wang, Jinping & Zhu, Bin, 2022. "Synergistic effect of sodium content for tuning Sm2O3 as a stable electrolyte in proton ceramic fuel cells," Renewable Energy, Elsevier, vol. 193(C), pages 608-616.
    10. Luo, Yu & Liao, Shuting & Chen, Shuai & Fang, Huihuang & Zhong, Fulan & Lin, Li & Zhou, Chen & Chen, Chongqi & Cai, Guohui & Au, Chak-Tong & Jiang, Lilong, 2022. "Optimized coupling of ammonia decomposition and electrochemical oxidation in a tubular direct ammonia solid oxide fuel cell for high-efficiency power generation," Applied Energy, Elsevier, vol. 307(C).
    11. Shah, M.A.K. Yousaf & Lu, Yuzheng & Mushtaq, Naveed & Yousaf, Muhammad & Akbar, Nabeela & Xia, Chen & Yun, Sining & Zhu, Bin, 2023. "Semiconductor-membrane fuel cell (SMFC) for renewable energy technology," Renewable and Sustainable Energy Reviews, Elsevier, vol. 185(C).
    12. Wang, Chaoqi & Lü, Zhe & Li, Jingwei & Cao, Zhiqun & Wei, Bo & Li, Huan & Shang, Minghao & Su, Chaoxiang, 2020. "Efficient use of waste carton for power generation, tar and fertilizer through direct carbon solid oxide fuel cell," Renewable Energy, Elsevier, vol. 158(C), pages 410-420.
    13. Choi, Sung Min & An, Hyegsoon & Yoon, Kyung Joong & Kim, Byung-Kook & Lee, Hae-Weon & Son, Ji-Won & Kim, Hyoungchul & Shin, Dongwook & Ji, Ho-Il & Lee, Jong-Ho, 2019. "Electrochemical analysis of high-performance protonic ceramic fuel cells based on a columnar-structured thin electrolyte," Applied Energy, Elsevier, vol. 233, pages 29-36.
    14. Jolaoso, Lateef A. & Yousuf, Abu & Liu, Fan & Duan, Chuancheng & Kazempoor, Pejman, 2024. "Efficient Energy Storage via Methane Production Using Protonic Ceramic Electrochemical Cells," Applied Energy, Elsevier, vol. 369(C).

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