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All issues Volume 361 (2026) EPJ Web Conf., 361 (2026) 07001 References
Open Access
Issue
EPJ Web Conf.
Volume 361, 2026
ASPOWERCN 2024 – The 8th Joint Conference of Aerospace Propulsion and the 44th Aerospace Propulsion Technology Information Society (APTIS) Technical Conference
Article Number 07001
Number of page(s) 11
Section New Energy and Advanced Propulsion
DOI https://doi.org/10.1051/epjconf/202636107001
Published online 13 April 2026
  1. Fernandes M D, S D P Andrade, V N Bistritzki, 等. SOFC-APU systems for aircraft: A review [J]. 2018, 43(33): 16311–33. [Google Scholar]
  2. Yong S T, C W Ooi, S-P Chai, 等. Review of methanol reforming-Cu-based catalysts, surface reaction mechanisms, and reaction schemes [J]. 2013, 38(22): 9541–52. [Google Scholar]
  3. Sá S, H Silva, L Brandão, 等. Catalysts for methanol steam reforming—A review [J]. 2010, 99(1-2): 43–57. [Google Scholar]
  4. Herdem M S, M Y Sinaki, S Farhad, 等. An overview of the methanol reforming process: Comparison of fuels, catalysts, reformers, and systems [J]. 2019, 43(10): 5076–105. [Google Scholar]
  5. Liu H, J Qin, X Xiu, 等. Comparative study of fuel types on solid oxide fuel cell–gas turbine hybrid system for electric propulsion aircraft [J]. 2023, 347: 128426. [Google Scholar]
  6. Peksen M, R Peters, L Blum, 等. Numerical modelling and experimental validation of a planar type pre-reformer in SOFC technology [J]. 2009, 34(15): 6425–36. [Google Scholar]
  7. Klenov O, L Makarshin, A Gribovskiy, 等. CFD modeling of compact methanol reformer [J]. 2015, 282: 91–100. [Google Scholar]
  8. Wismann S T, J S Engbaek, S B Vendelbo, 等. Electrified methane reforming: Elucidating transient phenomena [J]. 2021, 425: 131509. [Google Scholar]
  9. Cimenti M, V Alzate-Restrepo, J M J J O P S Hill. Direct utilization of methanol on impregnated Ni/YSZ and Ni–Zr0. 35Ce0. 65O2/YSZ anodes for solid oxide fuel cells [J]. 2010, 195(13): 4002–12. [Google Scholar]
  10. Liu M, R Peng, D Dong, 等. Direct liquid methanol-fueled solid oxide fuel cell [J]. 2008, 185(1): 188–92. [Google Scholar]
  11. Jiang Y, A V J J O T E S Virkar. A high performance, anode-supported solid oxide fuel cell operating on direct alcohol [J]. 2001, 148(7): A706. [Google Scholar]
  12. Agarwal V, S Patel, K J A C A G Pant. H2 production by steam reforming of methanol over Cu/ZnO/Al2O3 catalysts: transient deactivation kinetics modeling [J]. 2005, 279(1-2): 155–64. [Google Scholar]
  13. Purnama H, T Ressler, R E Jentoft, 等. CO formation/selectivity for steam reforming of methanol with a commercial CuO/ZnO/Al2O3 catalyst [J]. 2004, 259(1): 83–94. [Google Scholar]
  14. Karim A, J Bravo, A J A C A G Datye. Nonisothermality in packed bed reactors for steam reforming of methanol [J]. 2005, 282(1-2): 101–9. [Google Scholar]
  15. Agrell J, H Birgersson, M J J O P S Boutonnet. Steam reforming of methanol over a Cu/ZnO/Al2O3 catalyst: a kinetic analysis and strategies for suppression of CO formation [J]. 2002, 106(1-2): 249–57. [Google Scholar]
  16. Fukahori S, H Koga, T Kitaoka, 等. Steam reforming behavior of methanol using paper-structured catalysts: experimental and computational fluid dynamic analysis [J]. 2008, 33(6): 1661–70. [Google Scholar]
  17. Yang B, Y Liu, J Zhu, 等. The Performance of Solid Oxide Fuel Cells Based on Methanol Solution [J]. 2023, 111(6): 1575. [Google Scholar]

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