Structural, electrical, and electrochemical properties of cobalt-doped NiFe2O4 as a potential cathode material for solid oxide fuel cells

International Journal of Hydrogen Energy

Volumn 38, Issue 33, 2013, Pages 14329-14336

  Rao, Yuanyuan ^a   Wang, Zhenbin ^a   Chen, Long ^a   Wu, Ruofei ^a   Peng, Ranran ^a   Lu, Yalin ^a,b  

^a UNIVERSITY OF SCIENCE AND TECHNOLOGY OF CHINA   (China)

^b UNIVERSITY OF SCIENCE AND TECHNOLOGY OF CHINA   (China)

Author keywords

Cathode; Electrical conductivity; Single phase electrode; Solid oxide fuel cell; Spinel material

Indexed keywords

ELECTRICAL CONDUCTIVITY; ELECTRONIC AND IONIC CONDUCTIVITY; ELECTRONIC CONDUCTIVITY; INTERMEDIATE TEMPERATURE SOLID OXIDE FUEL CELL; MAXIMUM POWER DENSITY; OCTAHEDRAL INTERSTITIAL SITE; POLARIZATION RESISTANCES; SPINEL MATERIALS;

BINDING ENERGY; DOPING (ADDITIVES); ELECTRIC CONDUCTIVITY; IONIC CONDUCTIVITY; SOLID OXIDE FUEL CELLS (SOFC);

CATHODES;

EID: 84886086111     PISSN: 03603199     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.ijhydene.2013.08.097     Document Type: Article

References (43)

1. E.D. Wachsman, and K.T. Lee Lowering the temperature of solid oxide fuel cells Science 334 2011 935 939
2. 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
3. H. Ullmann, N. Trofimenko, F. Tietz, D. Stöver, and A. Ahmad-Khanlou Correlation between thermal expansion and oxide ion transport in mixed conducting perovskite-type oxides for SOFC cathodes Solid State Ionics 138 2000 79 90
4. 3 cathodes for low-temperature SOFCs Solid State Ionics 149 2002 11 19
5. +-SOFC cathodes J Mater Chem 22 2012 16017 16025
6. 4+δ J Mater Chem 13 2003 1136 1144
7. S.P. Jiang, J.P. Zhang, and X. Zheng A comparative investigation of chromium deposition at air electrodes of solid oxide fuel cells J Eur Ceram Soc 22 2002 361 373
8. Y.D. Zhen, A.I. Tok, F.Y.C. Boey, and S.P. Jiang Development of Cr-tolerant cathodes of solid oxide fuel cells Electrochemical Solid-state Lett 11 2008 B42 B46
9. 4: a versatile spinel material brings new opportunities for spintronics Adv Mater 18 2006 1733 1736
10. 3-forming interconnects of solid oxide fuel cells Int J Hydrogen Energy 34 2009 9220 9226
11. A. Petric, and H. Ling Electrical conductivity and thermal expansion of spinels at elevated temperatures J Am Ceram Soc 90 2007 1515 1520
12. 3-δ perovskites as cathodes of solid oxide fuel cells Int J Hydrogen Energy 36 2011 3179 3186
13. 3-δ perovskite cathodes J Electrochem Soc 158 2011 B132 B138
14. 3 (x = 0.0-0.5) J Mater Chem 12 2002 3787 3791
15. Z.T. Tao, L. Bi, L.T. Yan, W.P. Sun, Z.W. Zhu, and R.R. Peng A novel single phase cathode material for a proton-conducting SOFC Electrochem Commun 11 2009 688 690
16. 3-δ for proton conducting solid oxide fuel cell Electrochem Commun 13 2011 1070 1073
17. C.J. Zhang, and H.L. Zhao A novel cobalt-free cathode material for proton-conducting solid oxide fuel cells J Mater Chem 22 2012 18387 18394
18. 3: a single phase air electrode material for reversible solid oxide cells Int J Hydrogen Energy 37 2012 12522 12527
19. 3 electrolyte thin film Solid State Ionics 177 2006 389 393
20. 3-δ hydrogen electrodes as effective reduction barriers for reversible solid oxide cells based on doped ceria electrolyte thin film J Power Sources 199 2012 142 145
21. 3-δ as a potential SOFC anode Solid State Ionics 179 2008 1588 1592
22. G. Kresse, and J. Furthmiiller Efficiency of ab-initio total energy calculations for metals and semiconductors using a plane-wave basis set Comput Mater Sci 6 1996 15 50
23. P.E. Blöchl Projector augmented-wave method Phys Rev B 50 1994 17953 17979
24. J.P. Perdew, K. Burke, and M. Ernzerhof Generalized gradient approximation made simple Phys Rev Lett 77 1996 3865 3868
25. H.J. Monkhorst, and J.D. Pack Special points for Brillouin-zone integrations Phys Rev B 13 1976 5188 5192
26. S.L. Dudarev, G.A. Botton, S.Y. Savrasov, C.J. Humphreys, and A.P. Sutton Electron-energy-loss spectra and the structural stability of nickel oxide: an LSDA1U study Phys Rev B 57 1998 1505 1509
27. O. Bengone, M. Alouani, P. Blöchl, and J. Huge Implementation of the projector augmented-wave LDA+U method: application to the electronic structure of NiO Phys Rev B 62 2000 16392 16401
28. L. Wang, T. Maxisch, and G. Ceder Oxidation energies of transition metal oxides within the GGA+U framework Phys Rev B 73 2006 195107 195113
29. S.C. Paulson, Y. Yoo, and V.I. Birss Chromium poisoning of SOFC cathodes:influence of the LSM-YSZ structure Proc Electrochem Soc 07 2005 1584 1597
30. Y.X. Zhang, and C.R. Xia A durability model for solid oxide fuel cell electrodes in thermal cycle processes J Power Sources 195 2010 6611 6618
31. 3-δ as cathode materials for IT-SOFC J Power Sources 176 2008 107 111
32. H. Hayashi, M. Kanoh, J.C. Quan, H. Inaba, S.R. Wang, and M. Dokiya Thermal expansion of Gd-doped ceria and reduced ceria Solid State Ionics 132 2000 227 233
33. 3 based oxide ion conductor J.Electrochem Soc 145 1998 3177 3183
34. 3-δ (0.3 ≤ x ≤ 0.7) J Eur Ceram Soc 26 2006 2827 2832
35. 3 as cathode material for intermediate-temperature solid oxide fuel cells J Power Sources 196 2011 999 1005
36. 3 (0 ≤ x ≤ 0.3) J Mater Chem 7 1997 2499 2503
37. 3-δ (M = Sr, Ba, Ca) J Electrochem Soc 143 1996 2722 2729
38. L. Kindermann, F.W. Poulsen, P.H. Larsen, H. Nickel, and K. Hilpert Synthesis and properties of La-Sr-Mn-Fe-O based perovskites P. Stevens, Proc. 3rd Eur. solid oxide fuel cell forum, Switzerland 1998 123 132
39. 3 Solid State Ionics 76 1995 259 271
40. 3 Solid State Ionics 76 1995 273 283
41. 3-δ cathode in solid oxide fuel cells: a First-Principles Study J Mater Chem 2013 10.1039/C3TA11554B
42. X.Y. Xu, Z.Y. Jiang, X. Fan, and C.R. Xia LSM-SDC electrodes fabricated with an ion-impregnating process for SOFCs with doped ceria electrolytes Solid State Ionics 177 2006 2113 2117
43. V. Dusastre, and J.A. Kilner Optimisation of composite cathodes for intermediate temperature SOFC applications Solid State Ionics 126 1999 163 174