參考文獻 |
[1] W.H. Kan, A.J. Samson, V. Thangadurai, Trends in electrode development for next generation solid oxide fuel cells, J. Mater. Chem. A. 4 (2016) 17913-17932.
[2] P. Dockrill, It’s Official: Atmospheric CO2 Just Exceeded 415 ppm For The First Time in Human History, 2019
(https://www.sciencealert.com/it-s-official-atmospheric-co2-just-exceeded-415-ppm-for-first-time-in-human-history).
[3] 吳佩真,加壓鈕扣型陽極支撐SOFC實驗量測與活化和濃度過電位分析計算,國立中央大學碩士論文,2013
(https://hdl.handle.net/11296/bj6x23).
[4] V.A.C. Haanappel, M.J. Smith, A review of standardising SOFC measurementand quality assurance at FZJ, J. Power Sources 171 (2007) 169-178.
[5] N. Mahato, A. Banerjee, A. Gupta, S. Omar, K. Balani, Progress in material selection for solid oxide fuel cell technology: A review, Prog. Mater. Sci. 72 (2015) 141-337.
[6] K. Wanga, D. Hissela, M.C. Péra, N. Steiner, D. Marra, M. Sorrentino, C. Pianese, M. Monteverde, P. Cardone, J. Saarinene, A Review on solid oxide fuel cell models, Int. J. Hydrog. Energy 12 (2011) 7212-7228.
[7] 左峻德,SOFC技術標準與安規及應用市場研析, 行政院原子能委員會委託研究計畫研究報告,2001。
[8] 洪永杰,固態氧化物燃料電池專利檢索與分析報告,元智大學,2005。
[9] Y. Itagaki, J. Cui, N. Ito, H. Aono, H. Yahiro, Effect of Ni-loading on Sm-doped CeO2 anode for ammonia-fueled solid oxide fuel cell, J. Ceram. Soc. Japan 126 (2018) 870-876.
[10] M. Hashinokuchi, M. Zhang, T. Doi, M. Inaba, Enhancement of anode activity and stability by Cr addition at Ni/Sm-doped CeO2 cermet anodes in NH3-fueled solid oxide fuel cells, Solid State Ionics 319 (2018) 180-185.
[11] M. Hashinokuchi, R. Yokochi, W. Akimoto, T. Doi, M. Inaba, J. Kugai, Enhancement of anode activity at Ni/Sm-doped CeO2 cermet anodes by Mo addition in NH3-fueled solid oxide fuel cells, Solid State Ionics 285 (2016) 222-226.
[12] W. Akimoto, T. Fujimoto, M. Saito, M. Inaba, H. Yoshida, Toru Inagaki, Ni–Fe/Sm-doped CeO2 anode for ammonia-fueled solid oxide fuel cells, Solid State Ionics 256 (2014) 1-4.
[13] S.C. Singhal, K. Kendal, High Temperature Solid Oxide Fuel Cells: Fundamentals, Design and Applications, Elsevier Technology, New York, 2003.
[14] Y. Patcharavorachot, A. Arpornwichanop, A. Chuachuensuk, Electrochemical study of a planar solid oxide fuel cell: Role of support structures, J. Power Sources 177 (2008) 254 - 261.
[15] S.H. Chan, K.A. Khor, Z.T. Xia, A complete polarization model of a solid oxide fuel cell and its sensitivity to the change of cell component thickness, J. Power Sources 93 (2001) 130-140.
[16] S.H. Chan, Z.T. Xia, Polarization effects in electrolyte/electrode-supported solid oxide fuel cells, J. Appl. Electrochem. 32 (2002) 339-347.
[17] F. Miao, Impact on fuel transport efficiency in anode of planar solid oxide fuel cells, Int. J. Electrochem. Sci 8 (2013) 11814-11822
[18] G. Cinti, G. Discepoli, E. Sisania, U. Desideri, SOFC operating with ammonia: Stack test and system analysis, Int. J. Hydrog. Energy 41 (2016) 13583-13590
[19] N. Minha, J. Mizusakib, S. C. Singhal, Advances in solid oxide fuel cells: Review of progress through three decades of the international symposia on solid oxide fuel cells, J. Electrochem. Soc. 78 (2017) 63-67
[20] M. Xua, T. Li, M. Yang, M. Andersson, Solid oxide fuel cell interconnect design optimization considering the thermal stresses, Sci. Bull. 61 (2016) 1333-1344
[21] G. Meng, C. Jiang, J. Ma, Q. Ma, X. Liu, Comparative study on the performance of a SDC-based SOFC fueled by ammonia and hydrogen, J. Power Sources 173 (2007) 189-193.
[22] M.B. Mogensen, M. Chen, H.L. Frandsen, C. Graves, J.B. Hansen, K. V. Hansen, A. Hauch, T. Jacobsen, S.H. Jensen, T.L. Skafte, X. Sun, Reversible solid-oxide cells for clean and sustainable energy, Clean Energy 3 (2019) 175-201
[23] A. Leonide, Y. Apel, E.I. Tiffee, SOFC modeling and parameter identification by means of impedance spectroscopy, J. Electrochem. Soc. 19 (2010) 81-109.
[24] J. Larminie, A. Dicks, Fuel Cell Systems Explained, Oxford Brookes University, UK, 2003.
[25] M. Henke, J. Kallo, K.A. Friedrich, W.G. Bessler, Influence of pressurisation on SOFC performance and durability: A theoretical study, Fuel Cells 11 (2011) 581-591.
[26] W.G. Bessler, S. Gewies, Gas concentration impedance of solid oxide fuel cell anodes: Channel geometry, J. Electrochem. Soc. 154 (2007) B548-B559.
[27] J.C. Njodzefon, D. Klotz, A. Kromp, A. Weber, E.I. Tiff´ee, Electrochemical modeling of the current-voltage characteristics of an SOFC in fuel cell and electrolyzer operation modes, J. Electrochem. Soc. 160 (2013) F313-F323.
[28] M. Ni, M.K.H. Leung, D.Y.C. Leung, Parametric study of solid oxide fuel cell performance, Energy Convers. and Manag. 48 (2007) 1525-1535.
[29] S. Primdahl, M. Mogensen, Gas conversion impedance: A test geometry effect in characterization of solid oxide fuel cell anodes, J. Electrochem. Soc. 145 (1998) 2431-2438.
[30] S. Yadav, M. K. Singh, K. Sudhakar, Modelling of solid oxide fuel cell- A review, J. Appl. Sci. Eng. 6 (2015) 2229-5518.
[31] S. Ahn, J. Tatarchuk, Air electrode: Identification of intraelectrode rate phenomena via ac impedance, J. Electrochem. Soc. 142 (1995) 4169-4175.
[32] T.E Springer, T.A. Zawodzinski, M.S Wilson, S. Gottesfeld. Characterization of polymer electrolyte fuel cell using impedance spectroscopy, J. Electrochem. Soc. 143 (1996) 587-599.
[33] J.R. MacDonald, Impedance Spectroscopy, Emphasizing Solid Materials and Systerms, Wiley Interscience, 1987.
[34] J. Wang, Analytical Electrochemistry, 3rd Ed., John Wiley & Sons, Inc., 2006.
[35] J. B. Jorcin, M. E. Orazem, N. P´eb`ere, B. Tribollet, CPE analysis by local electrochemical impedance spectroscopy, Electrochimica. Acta. 51 (2006) 1473-1479.
[36] C.H. Kim, S.I. Pyun, J.H. Kim, An investigation of the capacitance dispersion on the fractal carbon electrode with edge and basal orientations, Electrochimica Acta. 48 (2003) 3455-3463.
[37] A. Nakajo, Z. Wuillemin, P. Metzger, S. Diethelm, G. Schiller, J.V. Herlea, D. Favrata, Electrochemical model of solid oxide fuel cell for simulation at the stack scale, J. Electrochem. Soc. 158 (2011) B1083-B1101
[38] J. Wang, Realizations of generalized Warburg impedance with RC ladder networks and transmission lines, J. Electrochem. Soc. 134 (1987) 1915-1920.
[39] 洪藝庭,加壓型固態氧化物燃料電池之性能和穩定性量測,國立中央大學碩士論文,2018
(http://ir.lib.ncu.edu.tw/handle/987654321/79518).
[40] C. Zamfirescu, I. Dincer, Using ammonia as a sustainable fuel, J. Power Sources 185 (2008) 459-465.
[41] J.O. Jensen, A.P. Vestbø, Q. Li, N.J. Bjerrum, The energy efficiency of onboard hydrogen storage, J. Alloys Compd. 446-447 (2007) 723-728.
[42] S.H. Jensen, X. Sun, S.D. Ebbesen, R. Knibbe, M. Mogensen, Hydrogen and synthetic fuel production using pressurized solid oxide electrolysis cells, Int. J. Hydrog. Energy 35 (2010) 9544-9549.
[43] H. Sumi, Y.H. Lee, H. Muroyama, T. Matsui, M. Kamijo, S. Mimuro, M. Yamanaka, Y. Nakajima, K. Eguchi, Effect of carbon deposition by carbon monoxide disproportionation on electrochemical characteristics at low temperature operation for solid oxide fuel cells, J. Power Sources 196 (2011) 4451-4457.
[44] V.A. Restrepo, J.M. Hill, Carbon deposition on Ni/YSZ anodes exposed to CO/H2 feeds, J. Power Sources 195 (2010) 1344-1351.
[45] V. Subotic, B. Stoeckl, V. Lawlor, J. Strasser, H. Schroettner, C. Hochenauer, Towards a practical tool for online monitoring of solid oxide fuel cell operation: An experimental study and application of advanced data analysis approaches, Appl. Energy 222 (2018) 748-761.
[46] S. Savoie, T.W. Napporn, B. Morel, M. Meunier, R. Roberge, Catalytic activity of Ni-YSZ anodes in a single-chamber solid oxide fuel cell reactor, J. Power Sources 196 (2011) 3713-3721.
[47] J. Andersson, J. Lundgren, Techno-economic analysis of ammonia production via integrated biomass gasification, Appl. Energy 130 (2014) 484-490.
[48] A. Fuertea, R.X. Valenzuelaa, M.J. Escuderoa, L. Daza, Ammonia as efficient fuel for SOFC, J. Power Sources 192 (2009) 170-174.
[49] A.F.S. Molouk, J. Yang, T. Okanishi, H. Muroyama, T. Matsui, K. Eguchi, Electrochemical and catalytic behavior of Ni-based cermet anode for ammonia-fueled SOFCs, ECS Trans. 68 (2015) 2751-2762.
[50] S.S. Shy, S.C. Hsieh, H.Y. Chang, A pressurized ammonia-fueled anode-supported solid oxide fuel cell: Power performance and electrochemical impedance measurements, J. Power Sources 396 (2018) 80-87.
[51] A.F.S. Molouk, J. Yang, T. Okanishi, H. Muroyama, T. Matsui, K. Eguchi, Comparative study on ammonia oxidation over Ni-based cermet anodes for solid oxide fuel cells, J. Power Sources 305 (2016) 72-79.
[52] J. Yang, T. Akagi, T. Okanishi, H. Muroyama, T. Matsui, and K. Eguchi, Catalytic influence of oxide component in Ni‐based cermet anodes for ammonia‐fueled solid oxide fuel cells, Fuel cells 15 (2015) 390-397.
[53] J. Yang, A.F.S. Molouk, T. Okanishi, H. Muroyama, T. Matsui, K. Eguchi, A stability study of Ni/Yttria-stabilized Zirconia anode for direct ammonia solid oxide fuel cells, ACS Appl. 7 (2015) 28701-28707.
[54] A.F.S. Molouk, T. Okanishi, H. Muroyama, T. Matsui, K. Eguchi, Electrochemical and catalytic behaviors of Ni–YSZ Anode for the direct utilization of ammonia fuel in solid oxide fuel cells, J. Electrochem. Soc. 162 (2015) 1268-1274.
[55] J. Zhang, H.Y. Xu, W.Z. Li, Kinetic study of NH3 decomposition over Ni nanoparticles: The role of La promoter, structure sensitivity and compensation effect, Appl. Catal. A Gen. 296 (2005) 257-267.
[56] M.C.J. Bradford, P.E. Fanning, M.A. Vannice, Kinetics of NH3 decomposition over well dispersed Ru, J. Catal. 172 (1997) 479-484.
[57] A. Hashimoto, K. Kosaka, N. Matake, A. Yamashita, Y. Kobayashi, T. Kabata, K. Tomida, Anode reaction in pressurized solid oxide fuel cells, J. Power Energy Systems 4 (2010) 348-360.
[58] K. Okura, T. Okanishi, H. Muroyama, T. Matsui, K. Eguchi, Promotion effect of rare-earth elements on the catalytic decomposition of ammonia over Ni/Al2O3 catalyst, Appl. Catal. A Gen. 505 (2015) 77-85.
[59] K. Miyazaki, T. Okanishi, H. Muroyama, T. Matsui, K. Eguchi, Development of Ni-Ba(Zr,Y)O3 cermet anodes for direct ammonia-fueled solid oxide fuel cells, J. Power Sources 365 (2017) 148-154.
[60] T. Schober, H.G. Bohn, Water vapor solubility and electrochemical characterization of the high temperature proton conductor BaZr0.9Y0.1O2.95, Solid State Ion. 127 (2000) 351-360.
[61] J. Yang, A.F.S. Molouk, T. Okanishi, H. Muroyama, T. Matsui, K. Eguchi, Electrochemical and Catalytic Properties of Ni/BaCe0.75Y0.25O3−δ Anode for Direct Ammonia-Fueled Solid Oxide Fuel Cells, J. Am. Chem. Soc. l7 (2015) 7406-7412.
[62] M. Henke, C. Willich, C. Westner, F. Leucht, R. Leibinger, J. Kallo, K.A. Friedrich, Effect of pressure variation on power density and efficiency of solid oxide fuel cells, Electrochim Acta 66 (2012) 158-163.
[63] R.O. Hayre, S.W. Cha, W. Colella, F.B. Prinz, Fuel Cell Fundamentals, 2nd Ed., John Wiley & Sons Inc., New York, 2009.
[64] W.L. Lundberg, S.E. Veyo, M.D. Moeckel, A high-efficiency solid oxide fuel cell hybrid power system using the mercury 50 advanced turbine systems gas turbine, J. Eng. Gas Turbines Power 125 (2002) 51-58.
[65] S.B. Lee, T.H. Lim, R.H. Song, D.R. Shin, S.K. Dong, Development of a 700W anode-supported micro-tubular SOFC stack for APU applications, Int. J. Hydrog. Energy 33 (2008) 2330-2336.
[66] N. M. Sammes, Y. Du, R. Bove, Design and fabrication of a 100W anode supported micro-tubular SOFC stack, J. Power Sources 145 (2005) 428-434.
[67] D. Cui, L. Liu, Y. Dong, M. Cheng, Comparison of different current collecting modes of anode supported micro-tubular SOFC through mathematical modeling, J. Power Sources 174 (2007) 246-254.
[68] 梁俊德,加壓型SOFC碳沉積之實驗研究,國立中央大學碩士論文,2015 (https://hdl.handle.net/11296/tb6ujy).
[69] L.A. Chick, O.A. Marina, C.A. Coyle, E.C. Thomsen, Effects of temperature and pressure on the performance of a solid oxide fuel cell running on steam reformate of kerosene, J. Power Sources 236 (2012) 1-9.
[70] M. Stelter, A. Reinert, B.E. Mai, M. Kuznecov, Engineering aspects and hardware verification of a volume producible solid oxide fuel cell stack design for diesel auxiliary power units, J. Power Sources 154 (2006) 448-455.
[71] M. M. Hussain, X. Lia, I. Dincer, A general electrolyte–electrode-assembly model for the performance characteristics of planar anode-supported solid oxide fuel cells, J. Power Sources 189 (2009) 916-928.
[72] 李信宏,棋盤式雙極板尺寸流道效應對固態氧化物燃料電池性能之影響,國立中央大學碩士論文,2010
(https://hdl.handle.net/11296/w3zqzm).
[73] S. C. Singal, Solid oxide fuel cell for stationary, mobile, and military applications, Solid State Ion. 152 (2002) 405-410.
[74] M. Mogensen, K.V. Jensen, M. J. Jørgensen, S. Primdahl, Progress in understanding SOFC electrodes, Solid State Ion. 150 (2003) 123-129.
[75] Toyota Researching Natural Gas for Fuel Cells, Aiming for Zero Emissions Power at Its Production Plants (2017).
https://www.motortrend.com/news/toyota-researching-natural-gas-fuel-cells/
[76] K. Tomida, K. Kodo, D.Kobayashi, Y. Kato, S. Suemori, Y. Urashita, Efforts toward introduction of SOFC-MGT hybrid system to the market, Mitsubishi Heavy Ind. Tech. Rev. 55 (2018) 1-5.
|