參考文獻 |
[1] J. Larminie and A. Dicks, Fuel cell systems explained: Second edition. 2013.
[2] L. Carrette, K. A. Friedrich, and U. Stimming, “Fuel Cells - Fundamentals and Applications” Fuel Cells, vol. 1, no. 1, pp. 5–39, 2001.
[3] https://www.materialsnet.com.tw/industry/NewProductView.aspx?pid=1164
[4] http://www.taitung.gov.tw/News_Content.aspx?n=E4FA0485B2A5071E&s=0E1D042043578E1D
[5] file:///C:/Users/User/Downloads/201798152754%20.pdf
[6] http://www.secutech.com/15/download/Energy-saving_handbook.pdf
[7] https://toplus-e.com.tw/blog/19/81
[8] https://www.chinatimes.com/newspapers/20171027000388-260208?chdtv
[9] X. F. Ren, Q. Y. Lv, L. F. Liu, B. H. Liu, Y. R. Wang, A. Liu and G. Wu, “Current progress of Pt and Pt-based electrocatalysts used for fuel cells”, Sustainable Energy Fuels, vol. 4, pp. 15–30, 2020.
[10] S. Mclntosh, R. J. Gorte, “Direct hydrocarbon solid oxide fuel cells”, Chem. Rev., Vol. 104, pp. 4845-4866, 2004.
[11] C. Xia, M. Liu, “Novel cathodes for low‐temperature solid oxide fuel cells”, Adv. Mat., Vol. 14, pp. 521-523, 2002.
[12] S. Primdahl, “Nickel/yttria-stabilised zirconia cermet anodes for solid oxide fuel cells”, Netherlands: University of Twente, The Netherlands, 1999.
[13] J. Larminie, A. Dicks, “Fuel cell systems explained”, Second Edition ed: John Wiley & Sons, Ltd; 2003.
[14] L. Bi, E. H. Da’as, S. P. Shafi, “Proton-conducting solid oxide fuel cell (SOFC) with Y-doped BaZrO3 electrolyte”, Electrochem. Commun., Vol. 80, pp. 20-23, 2017.
[15] L. Malavasi, C. J. Fisher, M. S. Islam, “Oxide-ion and proton conducting electrolyte materials for clean energy applications: structural and mechanistic features”, Chem. Soc. Rev., Vol. 39, pp. 4370-4387, 2010.
[16] E. Fabbri, D. Pergolesi, E. Traversa, “Materials challenges toward proton-conducting oxide fuel cells: a critical review”, Chem. Soc. Rev., Vol. 39, pp. 4355-4369, 2010.
[17] H. Iwahara, “Oxide-ionic and protonic conductors based on perovskite-type oxides and their possible applications”, Solid State Ionics, Vol. 52, pp. 99-104, 1992.
[18] H. Iwahara, Y. Asakura, K. Katahira, M. Tanaka, “Prospect of hydrogen technology using proton-conducting ceramics”, Solid State Ionics, Vol. 168, pp. 299-310, 2004.
[19] H. Iwahara, H. Uchida, K. Ono, K. Ogaki, “Proton conduction in sintered oxides based on BaCeO3”, J. Electrochem. Soc., Vol. 135, pp. 529-533, 1988.
[20] K. D. Kreuer, “Proton-conducting oxide”, Annu. Rev. Mater. Res., Vol. 33, pp. 333-359, 2003.
[21] Y. M. Guo, Y. Lin, H. A. Shi, R. Ran, Z. P. Shao, “A high electrochemical performance proton conductor electrolyte with CO2 tolerance”, Chinese J. Catal., Vol. 30, pp. 479-481, 2009.
[22] Y. Okuyama, N. Ebihara, K. Okuyama, Y. Mizutani, “Improvement of protonic ceramic fuel cells with thin film BCZY electrolyte”, ECS Trans., Vol. 68, pp. 2545-2553, 2015.
[23] G. S. Reddy, R. Bauri, “Y and In-doped BaCeO3-BaZrO3 solid solutions: chemically stable and easily sinterable proton conducting oxides”, J. Alloys Compd., Vol. 688, pp. 1039-1046, 2016.
[24] S. Gopalan, A. V. Virkar, “Thermodynamic stabilities of SrCeO3 and BaCeO3 using a molten salt method and galvanic cells”, J. Electrochem. Soc., Vol. 140, pp. 1060-1065, 1993.
[25] F. L. Chen, O. T. Sørensen, G. Y. Meng, D. K. Peng, “Chemical stability study of BaCe0.9Nd0.1O3-δ high-temperature proton-conducting ceramic”, J. Mater. Chem., Vol. 7, pp. 481-485, 1997.
[26] Y. M. Guo, Y. Lin, R. Ran, Z. P. Shao, “Zirconium doping effect on the performance of proton-conducting BaZryCe0.8−yY0.2O3−δ (0.0 ≤ y ≤ 0.8) for fuel cell applications”, J. Power Sources, Vol. 193, pp. 400-407, 2009.
[27] A. Afif, N. Radenahmad, C. M. Lim, M. I. Petra, M. Aminullslam, S. M. H. Rahman, S. Eriksson, A. K. Azad, “Structural study and proton conductivity in BaCe0.7Zr0.25−xYxZn0.05O3 (x=0.05, 0.1, 0.15, 0.2 & 0.25)”, Int. J. Hydrogen Energy, Vol. 41, pp. 11823-11831, 2015.
[28] H. S. Spacil. “Electrical device including nickel-containing stabilized zirconia electrode”, US patent 3, 503, 8091970.
[29] C. W. Tanner, K. Z. Fung, A. V. Virkar, “The effect of porous composite electrode structure on solid oxide fuel cell performance: I. theoretical analysis”, J. Electrochem. Soc., Vol. 144, pp. 21-30, 1997.
[30] R. J. Gorte, J. M. Vohs, “Nanostructured anodes for solid oxide fuel cells”, Curr. Opin. Colloid Interface Sci., Vol. 14, pp. 236-244, 2009.
[31] E. Fabbri, D. Pergolesi, E. Traversa, “Electrode materials: A challenge for the exploitation of protonic solid oxide fuel cells”, Sci. Technol. Adv. Mater., Vol. 11, pp. 044301, 2010.
[32] T. Matsui, R. Kishida, H. Muroyama, K. Eguchi, “Comparative study on performance stability of Ni-oxide cermet anodes under humidified atmospheres in solid oxide fuel cells”, J. Electrochem. Soc., Vol. 159, pp. F456-F460, 2012.
[33] S. M. Fang, K. Brinkman, F. L. Chen, “Unprecedented CO2 promoted hydrogen permeation in Ni-BaZr0.1Ce0.7Y0.1Yb0.1O3−δ membrane”, Appl. Mater. Interfaces, Vol. 6, pp. 725-730, 2014.
[34] G. C. Mather, F. M. Figueiredo, J. R. Jurado, J. R. Frade, “Synthesis and characterization of cermet anodes for SOFCs with a proton-conducting ceramic phase”, Solid State Ionics, Vol. 162, pp. 115-120, 2003.
[35] W. G. Coors, A. Manerbino, “Characterization of composite cermet with 68 wt% NiO and BaCe0.2Zr0.6Y0.2O3−δ”, J. Membr. Sci., Vol. 376, pp. 50-55, 2011.
[36] L. Bi, E. Fabbri, Z. Sun, E. Traversa, “BaZr0.8Y0.2O3−δ-NiO composite anodic powders for proton-conducting SOFCs prepared by a combustion method”, J Electrochem. Soc., Vol. 158, pp. B797-B803, 2011.
[37] N. Narendar, G. C. Mather, P. A. N. Dias, D. P. Fagg, “The importance of phase purity in Ni-BaZr0.85Y0.15O3−δ cermet anodes–novel nitrate-free combustion route and electrochemical study”, RSC Adv., Vol. 3, pp. 859-869, 2013.
[38] L. Chevallier, M. Zunic, V. Esposito, E. D. Bartolomeo, E Traversa, “A wet-chemical route for the preparation of Ni-BaCe0.9Y0.1O3−δ cermet anodes for IT-SOFCs”, Solid State Ionics, Vol. 180, pp. 715-720, 2009.
[39] B. H. Rainwater, M. Liu, “A more efficient anode microstructure for SOFCs based on proton conductors”, Int. J. Hydrogen Energy, Vol. 37, pp. 18342-18348, 2012.
[40] L. Yang, C. Zuo, S. Wang, Z. Cheng, M. Liu. “A novel composite cathode for low-temperature SOFCs based on oxide proton conductors”, Adv. Mater., Vol. 20, pp. 3280-3283, 2008.
[41] H. S. Song, S. Lee, S. H. Hyun, J. Kim, J. Moon, “Compositional influence of LSM-YSZ composite cathodes on improved performance and durability of solid oxide fuel cells”, J. Power Sources, Vol. 187, pp. 25-31, 2009.
[42] R. Peng, T. Wu, W. Liu, X. Liu, G. Meng, “Cathode processes and materials for solid oxide fuel cells with proton conductors as electrolytes”, J. Mater. Chem, Vol. 20, pp. 6218-6225, 2010.
[43] J. Dailly, S. Fourcade, A. Largeteau, F. Mauvy, J. C. Grenier, M. Marrony, “Perovskite and A2MO4-type oxides as new cathode materials for protonic solid oxide fuel cells”, Electrochim. Acta, Vol. 55, pp. 5847-5853, 2010.
[44] Choi, S.; Kucharczyk, C.J.; Liang, Y.; Zhang, X.; Takeuchi, I.; Ji, H.-I.; Haile, S.M. Exceptional power density and stability at intermediate temperatures in protonic ceramic fuel cells. Nat. Energy, Vol. 3, pp. 202-210, 2018.
[45] Y . Lin, Z. Zhan, J. L iu, S. A. Barnett, Direct operatio n of solid oxide furl cells with methane fuel, Solid State Ionics , Vol. 176 , pp. 1827-1835, 2005.
[46] Argyle, M. D.; Bartholomew, C. H. Heterogeneous Catalyst Deactivation and Regeneration: A Review Catalysts, Vol. 5 (1), pp. 145-269, 2015.
[47] J. J. Spivey, “Deactivation of Reforming Catalysts”, Fuel Cells: Technologies for Fuel Processing, pp. 285-315, 2011.
[48] H. Kim, C. Lu, W. L. Worrell, J. M. Vohs, R. J. Gorte, “Cu-Ni cermet anodes for direct oxidation of methane in solid-oxide fuel cells”, J. Electrochem. Soc., Vol. 149, pp. A247-A250, 2002.
[49] M. L. Toebes, J. H. Bitter, A. J. V. Dillen, K. P. D. Jong, “Impact of the structure and reactivity of nickel particles on the catalytic growth of carbon nanofibers”, Cat. Today, Vol. 76, pp. 33-42, 2002.
[50] K. Wei, X. X. Wang, R. A. Budiman, J. H. Kang, B. Lin, F. B. Zhou, Y. H. Ling, “Progress in Ni-based anode materials for direct hydrocarbon solid oxide fuel cells”, J. Mater. Sci., Vol. 53, pp. 8747-8765, 2018.
[51] A. K. Chatterjee, R. Banerjee, M. Sharon, “Enhancement of hydrogen oxidation activity at a nickel coated carbon beads electrode by cobalt and iron”, J. Power Sources, Vol. 137, pp. 216-221, 2004.
[52] C. K. Cho, B. H. Choi, K. T. Lee, “Effect of Co alloying on the electrochemical performance of Ni-Ce0.8Gd0.2O1.9 anodes for hydrocarbon-fueled solid oxide fuel cells”, J. Alloys Compd., Vol. 541, pp. 433-439, 2012.
[53] J. Ayawanna, D. Wattanasiriwech, Suthee Wattanasiriwech, Kazunori Sato, “Electrochemical performance of Ni1-xCox-GDC cermet anodes for SOFCs”, Energy Procedia, Vol. 34, pp. 439-448, 2013.
[54] R. Nishida, P. Puengjinda, H. Nishino, K. Kakinuma, M. E. Brito, M. Watanabe, H. Uchida, “High-performance electrodes for reversible solid oxide fuel cell/solid oxide electrolysis cell: Ni–Co dispersed ceria hydrogen electrodes”, RSC Adv., Vol. 4, pp. 16260-16266, 2014.
[55] T. Guo, X. L. Dong, M. M. Shirolkar, X. Song, M. Wang, L. Zhang, M. Li, H. Q. Wang, “Effects of cobalt addition on the catalytic activity of the Ni-YSZ anode functional layer and the electrochemical performance of solid oxide fuel cells”, ACS Appl. Mater. Interfaces, Vol. 6, pp. 16131-16139, 2014.
[56] J. C. W. Mah, A. Muchtar, M. R. Somalu, M. J. Ghazali, “Metallic interconnects for solid oxide fuel cell: A review on protective coating and deposition techniques”, Int. J. Hydrogen Energy, Vol. 42, pp. 9219-9229, 2017.
[57] W. Nicharee, S. Chaianansutcharit, K. Sato, “Electrochemical performance and stability of Ni1-xCox-based cermet anode for direct methane-fuelled solid oxide fuel cells”, MATEC Web of Conferences, Vol. 130, pp. 3005-3009, 2017.
[58] G. C. Ding, T. Gan, J. Yu, P. Li, X. L. Yao, N. J. Hou, L. J. Fan, Y. C. Zhao, Y. D. Li, “Carbon-resistant Ni1-xCox-Ce0.8Sm0.2O1.9 anode for solid oxide fuel cells fed with methanol”, Catal. Today, Vol. 298, pp. 250-257, 2017.
[59] M. S. Fan, A. Z. Abdullah, S. Bhatia, “Utilization of greenhouse gases through carbon dioxide reforming of methane over Ni-Co/MgO-ZrO2: preparation, characterization and activity studies”, Appl. Catl. B-Environ., Vol. 100, pp. 365-377, 2010.
[60] J. G. Zhang, H. Wang, A. K. Dalai, “Development of stable bimetallic catalysts for carbon dioxide reforming of methane”, J. Catal., Vol. 249, pp. 300-310, 2007.
[61] W. Tu, M. Ghoussoub, C. V. Singh, Y. H. C. Chin, “Consequences of surface oxophilicity of Ni, Ni-Co, and Co clusters on methane activation”, J. Am. Chem. Soc., Vol. 139, pp. 6928-6945, 2017.
[62] http://www.dengyng.com.tw/htm/dy_p10.htm.
[63] K. Katahira, Y. Kohchi, T. Shimura, and H. Iwahara, “Protonic conduction in Zr-substituted BaCeO3”, Solid State Ionics, Vol. 138, pp. 91-98, 2000.
[64] Z. Wang, J. Qian, J. Cao, S. Wang, T. Wen, “A study of multilayer tape casting method for anode-supported planar type solid oxide fuel cells (SOFCs)”, Journal of Alloys and Compounds, Vol. 437 (1-2), pp.264-268, 2007.
[65] J. M. Serra and W. A. Meulenberg, “Thin‐Film Proton BaZr0.85Y0.15O3 Conducting Electrolytes: Toward an Intermediate‐Temperature Solid Oxide Fuel Cell Alternative”, Journal of the American Ceramic Society, Vol. 90, pp. 2082-2089, 2007.
[66] Q.-A.Huang, R. Hui, B. W. Wang, J. J. Zhang, “A review of AC impedance modeling and validation in SOFC diagnosis”, Electrochimica Acta, Vol. 52, Issue 28, pp. 8144-8164, 2007.
[67] G. Chiodelli, L. Malavasi, “Electrochemical open circuit voltage (OCV) characterization of SOFC materials”, Ionics, Vol. 19, pp. 1135-1144, 2013.
[68] D. B. Ingram and S. Linicz, “First-Principles Analysis of the Activity of Transition and Noble Metals in the Direct Utilization of Hydrocarbon Fuels at Solid Oxide Fuel Cell Operating Conditions”, Journal of The Electrochemical Society, Vol. 156, pp.B1457-B1465, 2009.
[69] Lu Zhou, Moussab Harb, Mohamed Nejib Hedhili, Noor Al Mana and Jean Marie Basset, “Microemulsion prepared Ni88Pt12 for methane cracking”, RSC Advances, Vol. 7, pp. 4078, 2017.
[70] Tushar V. Choudhary , Erhan Aksoylu & D. Wayne Goodman, “Nonoxidative Activation of Methane”, Catalysis Reviews: Science and Engineering, Vol. 45, pp. 151-203, 2003.
[71] Wesley Blanke Crow, M. E., M. S., “DIFFUSION OF COBALT, NICKEL, AND IRONIN COBALT OXIDE AND NICKEL OXIDE”, The Ohio State University, 1969.
[72] Jason D. Nicholas, Lutgard C. De Jonghe, “Prediction and evaluation of sintering aids for Cerium Gadolinium Oxide”, Solid State Ionics, Vol. 178, pp. 1187-1194, 2007.
[73] Yanhong Wan, Beibei He, Ranran Wang, Yihan Ling, Ling Zhao, “Effect of Co doping on sinterability and protonic conductivity of BaZr0.1Ce0.7Y0.1Yb0.1O3−δ for protonic ceramic fuel cells”, Journal of Power Sources, Vol. 347, pp. 14-20, 2017. |