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A direct-methane fuel cell with a ceria-based anode

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  • E. Perry Murray

    (Northwestern University)

  • T. Tsai

    (Northwestern University)

  • S. A. Barnett

    (Northwestern University)

Abstract

Fuel cells constitute an attractive power-generation technology that converts chemical energy directly and with high efficiency into electricity while causing little pollution. Most fuel cells require hydrogen as the fuel, but viable near-term applications will need to use the more readily available hydrocarbons, such as methane. Present-day demonstration power plants and planned fuel-cell electric vehicles therefore include a reformer that converts hydrocarbon fuel into hydrogen. Operating fuel cells directly on hydrocarbons would obviously eliminate the need for such a reformer and improve efficiency. In the case of polymer-electrolyte fuel cells, which have been studied for vehicle applications, the direct use of methanol fuel has been reported, but resulted in fuel permeating the electrolyte1,2. Solid oxide fuel cells — promising candidates for stationary power generation — can also use hydrocarbon fuel directly to generate energy, but this mode of operation resulted in either carbon deposition at high temperatures or poor power output at low operating temperatures3,4,5. Here we report the direct electrochemical oxidation of methane in solid oxide fuel cells that generate power densities upto 0.37 W cm−2 at 650 °C. This performance is comparable to that of fuel cells using hydrogen6,7 and is achieved by using ceria-containing anodes and low operating temperatures to avoid carbon deposition. We expect that the incorporation of more advanced cathodes would further improve the performance of our cells, making this solid oxide fuel cell a promising candidate for practical and efficient fuel-cell applications.

Suggested Citation

  • E. Perry Murray & T. Tsai & S. A. Barnett, 1999. "A direct-methane fuel cell with a ceria-based anode," Nature, Nature, vol. 400(6745), pages 649-651, August.
    • Handle: RePEc:nat:nature:v:400:y:1999:i:6745:d:10.1038_23220
    DOI: 10.1038/23220
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    1. Fan, Liyuan & Li, Chao'en & van Biert, Lindert & Zhou, Shou-Han & Tabish, Asif Nadeem & Mokhov, Anatoli & Aravind, Purushothaman Vellayani & Cai, Weiwei, 2022. "Advances on methane reforming in solid oxide fuel cells," Renewable and Sustainable Energy Reviews, Elsevier, vol. 166(C).
    2. Cai, Weizi & Zhou, Qian & Xie, Yongmin & Liu, Jiang & Long, Guohui & Cheng, Shuang & Liu, Meilin, 2016. "A direct carbon solid oxide fuel cell operated on a plant derived biofuel with natural catalyst," Applied Energy, Elsevier, vol. 179(C), pages 1232-1241.
    3. Yu, Fangyong & Xiao, Jie & Zhang, Yapeng & Cai, Weizi & Xie, Yongmin & Yang, Naitao & Liu, Jiang & Liu, Meilin, 2019. "New insights into carbon deposition mechanism of nickel/yttrium-stabilized zirconia cermet from methane by in situ investigation," Applied Energy, Elsevier, vol. 256(C).
    4. Hu, Boxun & Keane, Michael & Patil, Kailash & Mahapatra, Manoj K. & Pasaogullari, Ugur & Singh, Prabhakar, 2014. "Direct methanol utilization in intermediate temperature liquid-tin anode solid oxide fuel cells," Applied Energy, Elsevier, vol. 134(C), pages 342-348.
    5. Jiao, Yong & Zhang, Liqin & An, Wenting & Zhou, Wei & Sha, Yujing & Shao, Zongping & Bai, Jianping & Li, Si-Dian, 2016. "Controlled deposition and utilization of carbon on Ni-YSZ anodes of SOFCs operating on dry methane," Energy, Elsevier, vol. 113(C), pages 432-443.
    6. Wang, Lu & Wei, Yi-Ming & Brown, Marilyn A., 2017. "Global transition to low-carbon electricity: A bibliometric analysis," Applied Energy, Elsevier, vol. 205(C), pages 57-68.
    7. Milanese, Marco & Colangelo, Gianpiero & Laforgia, Domenico & de Risi, Arturo, 2017. "Multi-parameter optimization of double-loop fluidized bed solar reactor for thermochemical fuel production," Energy, Elsevier, vol. 134(C), pages 919-932.
    8. Shri Prakash, B. & Senthil Kumar, S. & Aruna, S.T., 2014. "Properties and development of Ni/YSZ as an anode material in solid oxide fuel cell: A review," Renewable and Sustainable Energy Reviews, Elsevier, vol. 36(C), pages 149-179.
    9. Park, Kwangjin & Lee, Sangho & Bae, Gyujong & Bae, Joongmyeon, 2015. "Performance analysis of Cu, Sn and Rh impregnated NiO/CGO91 anode for butane internal reforming SOFC at intermediate temperature," Renewable Energy, Elsevier, vol. 83(C), pages 483-490.
    10. Enrico Squizzato & Caterina Sanna & Antonella Glisenti & Paola Costamagna, 2021. "Structural and Catalytic Characterization of La 0.6 Sr 0.4 MnO 3 Nanofibers for Application in Direct Methane Intermediate Temperature Solid Oxide Fuel Cell Anodes," Energies, MDPI, vol. 14(12), pages 1-13, June.
    11. Wood, Thomas K. & Gurgan, Ilke & Howley, Ethan T. & Riedel-Kruse, Ingmar H., 2023. "Converting methane into electricity and higher-value chemicals at scale via anaerobic microbial fuel cells," Renewable and Sustainable Energy Reviews, Elsevier, vol. 188(C).
    12. 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.
    13. Sariboğa, Vedat & Öksüzömer, Faruk, 2012. "The investigation of active Ni/YSZ interlayer for Cu-based direct-methane solid oxide fuel cells," Applied Energy, Elsevier, vol. 93(C), pages 707-721.
    14. Berre Kumuk & Nisa Nur Atak & Battal Dogan & Salih Ozer & Pinar Demircioglu & Ismail Bogrekci, 2024. "Numerical and Thermodynamic Analysis of the Effect of Operating Temperature in Methane-Fueled SOFC," Energies, MDPI, vol. 17(11), pages 1-17, May.
    15. Eom, Seongyong & Ahn, Seongyool & Rhie, Younghoon & Kang, Kijoong & Sung, Yonmo & Moon, Cheoreon & Choi, Gyungmin & Kim, Duckjool, 2014. "Influence of devolatilized gases composition from raw coal fuel in the lab scale DCFC (direct carbon fuel cell) system," Energy, Elsevier, vol. 74(C), pages 734-740.
    16. Budzianowski, Wojciech M., 2016. "A review of potential innovations for production, conditioning and utilization of biogas with multiple-criteria assessment," Renewable and Sustainable Energy Reviews, Elsevier, vol. 54(C), pages 1148-1171.
    17. Xu, Han & Dang, Zheng, 2016. "Lattice Boltzmann modeling of carbon deposition in porous anode of a solid oxide fuel cell with internal reforming," Applied Energy, Elsevier, vol. 178(C), pages 294-307.
    18. Massimiliano Cimenti & Josephine M. Hill, 2009. "Direct Utilization of Liquid Fuels in SOFC for Portable Applications: Challenges for the Selection of Alternative Anodes," Energies, MDPI, vol. 2(2), pages 1-34, June.
    19. Saadabadi, S. Ali & Thallam Thattai, Aditya & Fan, Liyuan & Lindeboom, Ralph E.F. & Spanjers, Henri & Aravind, P.V., 2019. "Solid Oxide Fuel Cells fuelled with biogas: Potential and constraints," Renewable Energy, Elsevier, vol. 134(C), pages 194-214.
    20. Ke Ran & Fanlin Zeng & Lei Jin & Stefan Baumann & Wilhelm A. Meulenberg & Joachim Mayer, 2024. "in situ observation of reversible phase transitions in Gd-doped ceria driven by electron beam irradiation," Nature Communications, Nature, vol. 15(1), pages 1-10, December.
    21. Yue Teng & Ho Yeon Lee & Haesu Lee & Yoon Ho Lee, 2022. "Effect of Sputtering Pressure on the Nanostructure and Residual Stress of Thin-Film YSZ Electrolyte," Sustainability, MDPI, vol. 14(15), pages 1-9, August.
    22. Badwal, S.P.S. & Giddey, S. & Kulkarni, A. & Goel, J. & Basu, S., 2015. "Direct ethanol fuel cells for transport and stationary applications – A comprehensive review," Applied Energy, Elsevier, vol. 145(C), pages 80-103.
    23. 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.

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