Electrochemical study of lithiated transition metal oxide composite as symmetrical electrode for low temperature ceramic fuel cells

International Journal of Hydrogen Energy

Volumn 38, Issue 26, 2013, Pages 11398-11405

  Fan, Liangdong ^a,b,c   Zhang, Hongjuan ^b   Chen, Mingming ^b   Wang, Chengyang ^b   Wang, Hao ^c   Singh, Manish ^a   Zhu, Bin ^a,c  

^a ROYAL INSTITUTE OF TECHNOLOGY   (Sweden)

^b TIANJIN UNIVERSITY   (China)

^c HUBEI UNIVERSITY   (China)

Author keywords

Ceria carbonate; Electro catalytic activity; Hydration effect; Low temperature ceramic fuel cell; Symmetrical electrode; Transition metal oxide

Indexed keywords

CERIA-CARBONATE; ELECTROCATALYTIC ACTIVITY; HYDRATION EFFECTS; LOW TEMPERATURE CERAMICS; SYMMETRICAL ELECTRODES; TRANSITION-METAL OXIDES;

ACTIVATION ENERGY; CARBONATION; CATALYST ACTIVITY; CERAMIC MATERIALS; ELECTROCHEMICAL IMPEDANCE SPECTROSCOPY; ELECTROLYTES; ELECTROLYTIC REDUCTION; GAS FUEL PURIFICATION; HYDROGEN; METALLIC COMPOUNDS; TEMPERATURE; TRANSITION METALS;

ELECTROCHEMICAL ELECTRODES;

EID: 84882449820     PISSN: 03603199     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.ijhydene.2013.06.050     Document Type: Article

References (55)

1. 2-y/2 electrolytes for IT-SOFC operation at 500 C Solid State Ionics 129 2000 95 110
2. T. Hibino, A. Hashimoto, T. Inoue, J. Tokuno, S. Yoshida, and M. Sano A low-operating-temperature solid oxide fuel cell in hydrocarbon-air mixtures Science 288 2000 2031 2033
3. Z.P. Shao, and S.M. Haile A high-performance cathode for the next generation of solid-oxide fuel cells Nature 431 2004 170 173
4. E. Wachsman, and K. Lee Lowering the temperature of solid oxide fuel cells Science 334 2011 935 939
5. H. Da, X. Liu, F. Zeng, J. Qian, T. Wu, and Z. Zhan A micro-nano porous oxide hybrid for efficient oxygen reduction in reduced-temperature solid oxide fuel cells Scientific Rep 2 2012 462
6. B. Zhu, X. Liu, P. Zhou, X. Yang, Z. Zhu, and W. Zhu Innovative solid carbonate-ceria composite electrolyte fuel cells Electrochem Commun 3 2001 566 571
7. B. Zhu, X. Yang, J. Xu, Z. Zhu, S. Ji, and M. Sun Innovative low temperature SOFCs and advanced materials J Power Sources 118 2003 47 53
8. B. Zhu Functional ceria-salt-composite materials for advanced ITSOFC applications J Power Sources 114 2003 1 9
9. B. Zhu Next generation fuel cell R&D Int J Energy Res 30 2006 895 903
10. L. Fan, C. Wang, M. Chen, J. Di, J. Zheng, and B. Zhu Potential low-temperature application and hybrid-ionic conducting property of ceria-carbonate composite electrolytes for solid oxide fuel cells Int J Hydrogen Energy 36 2011 9987 9993
11. X. Li, G. Xiao, and K. Huang Effective ionic conductivity of a novel intermediate-temperature mixed oxide-ion and carbonate-ion conductor J Electrochem Soc 158 2011 B225 B232
12. L. Fan, C. Wang, J. Di, M. Chen, J. Zheng, and B. Zhu Study of ceria-carbonate nanocomposite electrolytes for low-temperature solid oxide fuel cells J Nanosci Nanotechnol 12 2012 4941 4945
13. D.M. Bastidas, S. Tao, and J.T.S. Irvine A symmetrical solid oxide fuel cell demonstrating redox stable perovskite electrodes J Mater Chem 16 2006 1603 1605
14. 3-δ as both anode and cathode material with improved microstructure in solid oxide fuel cells Electrochim Acta 52 2006 278 284
15. S.P. Jiang, L. Zhang, and Y. Zhang Lanthanum strontium manganese chromite cathode and anode synthesized by gel-casting for solid oxide fuel cells J Mater Chem 17 2007 2627 2635
16. Q. Liu, X. Dong, G. Xiao, F. Zhao, and F. Chen A novel electrode material for symmetrical SOFCs Adv Mater 22 2010 5478 5482
17. J.C. Ruiz-Morales, D. Marrero-Lopez, J. Canales-Vazquez, and J.T.S. Irvine Symmetric and reversible solid oxide fuel cells RSC Adv 1 2011 1403 1414
18. 6-δ, an electrode material for symmetric solid oxide fuel cells J Am Chem Soc 134 2012 6826 6833
19. 6-δ as a possible solid oxide fuel cell electrode J Power Sources 237 2013 13 18
20. M. Mat, X. Liu, Z. Zhu, and B. Zhu Development of cathodes for methanol and ethanol fuelled low temperature (300-600 C) solid oxide fuel cells Int J Hydrogen Energy 32 2007 796 801
21. Y. Zhao, D.-B. Xiong, H. Qin, F. Gao, H. Inui, and B. Zhu Nanocomposite electrode materials for low temperature solid oxide fuel cells using the ceria-carbonate composite electrolytes Int J Hydrogen Energy 37 2012 19351 19356
22. 4-Ag composite cathode for low temperature solid oxide fuel cells with ceria-carbonate composite electrolyte Int J Hydrogen Energy 37 2012 19388 19394
23. H. Qin, Z. Zhu, Q. Liu, Y. Jing, R. Raza, and S. Imran Direct biofuel low-temperature solid oxide fuel cells Energy Environ Sci 4 2011 1273 1276
24. L. Fan, B. Zhu, M. Chen, C. Wang, R. Raza, and H. Qin High performance transition metal oxide composite cathode for low temperature solid oxide fuel cells J Power Sources 203 2012 65 71
25. L. Fan, C. Wang, and B. Zhu Low temperature ceramic fuel cells using all nano composite materials Nano Energy 1 2012 631 639
26. C.H. Zhao, R.Z. Liu, L. Shao, S.R. Wang, and T.L. Wen Effects of CuO addition to anode on the electrochemical performances of cathode-supported solid oxide fuel cells Electrochem Commun 11 2009 2300 2303
27. 2 over nonreduced Zr-containing CuO/ZnO catalysts J Catal 223 2004 340 351
28. 2-NiO materials for the MCFC cathode application J Power Sources 160 2006 789 795
29. 3 nanocomposite electrolyte for low-temperature SOFCs Electrochem Commun 10 2008 1617 1620
30. B. Huang, G. Chen, F. Li, Q.C. Yu, and K.A. Hu Study of NiO cathode modified by rare earth oxide additive for MCFC by electrochemical impedance spectroscopy Electrochim Acta 49 2004 5055 5068
31. L. Fan, C. Wang, M. Chen, and B. Zhu Recent development of ceria-based (nano)composite materials for low temperature ceramic fuel cells and electrolyte-free fuel cells J Power Sources 234 2013 154 174
32. S.B. Adler Factors governing oxygen reduction in solid oxide fuel cell cathodes Chem Rev 104 2004 4791 4843
33. S.B. Adler, X.Y. Chen, and J.R. Wilson Mechanisms and rate laws for oxygen exchange on mixed-conducting oxide surfaces J Catal 245 2007 91 109
34. 3 composite cathodes Solid State Ionics 148 2002 27 34
35. Y. Li, R. Gemmen, and X. Liu Oxygen reduction and transportation mechanisms in solid oxide fuel cell cathodes J Power Sources 195 2010 3345 3358
36. A. Wijayasinghe, C. Lagergren, and B. Bergman New cathode materials for molten carbonate fuel cells Fuel Cells 2 2002 181 188
37. Y. Niu, F. Liang, W. Zhou, J. Sunarso, Z. Zhu, and Z. Shao A three-dimensional highly interconnected composite oxygen reduction reaction electrocatalyst prepared from a core-shell precursor ChemSusChem 4 2011 1582 1586
38. M. Mogensen, and S. Skaarup Kinetic and geometric aspects of solid oxide fuel cell electrodes Solid State Ionics 86-88 1996 1151 1160 Part 2
39. L. Fan, C. Wang, O. Osamudiamen, R. Raza, M. Singh, and B. Zhu Mixed ion and electron conductive composites for single component fuel cells: I. Effects of composition and pellet thickness J Power Sources 217 2012 164 169
40. J. Huang, Z. Mao, Z. Liu, and C. Wang Development of novel low-temperature SOFCs with co-ionic conducting SDC-carbonate composite electrolytes Electrochem Commun 9 2007 2601 2605
41. L. Fan, G. Zhang, M. Chen, C. Wang, J. Di, and B. Zhu Proton and oxygen ionic conductivity of doped ceria-carbonate composite by modified Wagner polarization Int J Electrochem Sci 7 2012 8420 8435
42. Y. Zhao, C. Xia, Y. Wang, Z. Xu, and Y. Li Quantifying multi-ionic conduction through doped ceria-carbonate composite electrolyte by a current-interruption technique and product analysis Int J Hydrogen Energy 37 2012 8556 8561
43. Y. Yin, S. Li, C. Xia, and G. Meng Electrochemical performance of gel-cast NiO-SDC composite anodes in low-temperature SOFCs Electrochim Acta 51 2006 2594 2598
44. Y. Choi, M.C. Lin, and M. Liu Rational design of novel cathode materials in solid oxide fuel cells using first-principles simulations J Power Sources 195 2010 1441 1445
45. 5+x as cathode material based on LSGM and GDC electrolyte for intermediate-temperature solid oxide fuel cells Int J Hydrogen Energy 37 2012 5914 5919
46. F. Liang, J. Chen, B. Chi, J. Pu, S.P. Jiang, and L. Jian Redox behavior of supported Pd particles and its effect on oxygen reduction reaction in intermediate temperature solid oxide fuel cells J Power Sources 196 2011 153 158
47. C. Xia, Y. Li, Y. Tian, Q. Liu, Z. Wang, and L. Jia Intermediate temperature fuel cell with a doped ceria-carbonate composite electrolyte J Power Sources 195 2010 3149 3154
48. C. Qin, and A. Gladney DFT study of and relevant to oxygen reduction with the presence of molten carbonate in solid oxide fuel cells Computational Theor Chem 999 2012 179 183
49. +-SOFC cathodes J Mater Chem 22 2012 16017 16025
50. E. Fabbri, L. Bi, D. Pergolesi, and E. Traversa Towards the next generation of solid oxide fuel cells operating below 600 C with chemically stable proton-conducting electrolytes Adv Mater 24 2011 195 208
51. 4 half cell for application in proton conducting solid oxide fuel cells Fuel Cells 13 2013 34 41
52. 3-δ composite cathode for solid oxide fuel cells with proton conducting electrolyte J Power Sources 194 2009 263 268
53. 2 (M = Co, Ni) cathode materials for intermediate temperature fuel cells by sol-gel processes Solid State Ionics 124 1999 53 59
54. R.A. Huggins, H. Prinz, M. Wohlfahrt-Mehrens, L. Jörissen, and W. Witschel Proton insertion reactions in layered transition metal oxides Solid State Ionics 70-71 1994 417 424
55. K. Ip, M.E. Overberg, Y.W. Heo, D.P. Norton, S.J. Pearton, and C.E. Stutz Hydrogen incorporation, diffusivity and evolution in bulk ZnO Solid-State Electron 47 2003 2255 2259