Fabrication and electrical properties of nanocrystalline Dy3+-doped CeO2 for intermediate-temperature solid oxide fuel cells

Energy

Volumn 55, Issue , 2013, Pages 304-309

  Park, K ^a   Hwang, H K ^a  

^a Sejong University   (South Korea)

Author keywords

Ceria; Electrical transport; Fuel cells; Oxides; Sintering

Indexed keywords

AMINO ACIDS; CERIUM COMPOUNDS; COMBUSTION; ELECTRIC CONDUCTIVITY; FUEL CELLS; GRAIN SIZE AND SHAPE; OXIDES; POWDERS; SOLID OXIDE FUEL CELLS (SOFC);

ELECTRICAL CONDUCTIVITY; ELECTRICAL TRANSPORT; HIGH ELECTRICAL CONDUCTIVITY; INTERMEDIATE TEMPERATURE SOLID OXIDE FUEL CELL; LOW SINTERING TEMPERATURE; OPERATING TEMPERATURE; SINTERING TEMPERATURES; SOLUTION COMBUSTION METHOD;

SINTERING;

ASPARTIC ACID; CERIUM; COMBUSTION; CRYSTAL PROPERTY; ELECTRICAL CONDUCTIVITY; ELECTRICAL PROPERTY; ELECTROLYTE; FUEL; FUEL CELL; HEATING; NANOTECHNOLOGY; OXIDE; PARTICLE SIZE; RARE EARTH ELEMENT; TEMPERATURE PROFILE;

EID: 84878657215     PISSN: 03605442     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.energy.2013.04.017     Document Type: Article

References (41)

1. Santin M., Traverso A., Magistri L., Massardo A. Thermoeconomic analysis of SOFC-GT hybrid systems fed by liquid fuels. Energy 2010, 35:1077-1083.
2. Komatsu Y., Kimijima S., Szmyd J.S. Performance analysis for the part-load operation of a solid oxide fuel cell-micro gas turbine hybrid system. Energy 2010, 35:982-988.
3. Wakui T., Yokoyama R. Optimal sizing of residential SOFC cogeneration system for power interchange operation in housing complex from energy-saving viewpoint. Energy 2012, 41:65-74.
4. Bunin G.A., Wuillemin Z., François G., Nakajo A., Tsikonis L., Bonvin D. Experimental real-time optimization of a solid oxide fuel cell stack via constraint adaptation. Energy 2012, 39:54-62.
5. 3+ co-doped ceria-based electrolytes for intermediate temperature solid oxide fuel cells. JAlloy Compd 2008, 464:310-316.
6. Chang H., Wang Y.M., Lin C.H., Cheng S.Y. Effects of rapid process on the conductivity of multiple elements doped ceria - based electrolyte. JPower Sources 2011, 196:1704-1711.
7. Liso V., Olesen A.C., Nielsen M.P., Kær S.K. Performance comparison between partial oxidation and methane steam reforming processes for solid oxide fuel cell (SOFC) micro combined heat and power (CHP) system. Energy 2011, 36:4216-4226.
8. Wakui T., Yokoyama R., Shimizu K. Suitable operational strategy for power interchange operation using multiple residential SOFC (solid oxide fuel cell) cogeneration systems. Energy 2010, 35:740-750.
9. Rokni M. Plant characteristics of an integrated solid oxide fuel cell cycle and a steam cycle. Energy 2010, 35:4691-4699.
10. Bang-Møller C., Rokni M., Elmegaard B. Exergy analysis and optimization of a biomass gasification, solid oxide fuel cell and micro gas turbine hybrid system. Energy 2011, 36:4740-4752.
11. Facchinetti E., Gassner M., D'Amelio M., Marechal F., Favrat D. Process integration and optimization of a solid oxide fuel cell - gas turbine hybrid cycle fueled with hydrothermally gasified waste biomass. Energy 2012, 41:408-419.
12. Jia J., Li Q., Luo M., Wei L., Abudula A. Effects of gas recycle on performance of solid oxide fuel cell power systems. Energy 2011, 36:1068-1075.
13. Lawlor V., Griesser S., Buchinger G., Olabi A.G., Cordiner S., Meissner D. Review of the micro-tubular solid oxide fuel cell: part I. Stack design issues and research activities. JPower Sources 2009, 193:387-399.
14. Kim H., Park S., Vohs J.M., Gorte R.J. Direct oxidation of liquid fuels in a solid oxide fuel cell. JElectrochem Soc 2001, 148:A693-A695.
15. Yoshida H., Miura K., Fukui T., Ohara S., Inagaki T. Sintering behavior of Ln-doped ceria compounds containing gallia. JPower Sources 2002, 106:136-141.
16. Gao L., Zhou M., Zheng Y., Gu H., Chen H., Guo L. Effect of zinc oxide on yttria doped ceria. JPower Sources 2010, 195:3130-3134.
17. Fergus J.W. Electrolytes for solid oxide fuel cells. JPower Sources 2006, 162:30-40.
18. Khandelwal M., Venkatasubramanian A., Prasanna T.R.S., Gopalan P. Correlation between microstructure and electrical conductivity in composite electrolytes containing Gd-doped ceria and Gd-doped barium cerate. JEur Ceram Soc 2011, 31:559-568.
19. Gil V., Larrea A., Merino R.I., Orera V.M. Redox behaviour of Gd-doped ceria-nickel oxide composites. JPower Sources 2009, 192:180-184.
20. Zha S., Xia C., Meng G. Effect of Gd (Sm) doping on properties of ceria electrolyte for solid oxide fuel cells. JPower Sources 2003, 115:44-48.
21. Kuharuangrong S. Ionic conductivity of Sm, Gd, Dy and Er-doped ceria. JPower Sources 2007, 171:506-510.
22. Piñol S., Morales M., Espiell F. Low temperature anode-supported solid oxide fuel cells based on gadolinium doped ceria electrolytes. JPower Sources 2007, 169:2-8.
23. Matovic B., Dohcevic-Mitrovic Z., Radovic M., Brankovic Z., Brankovic G., Boskovic S., et al. Synthesis and characterization of ceria based nanometric powders. JPower Sources 2009, 193:146-149.
24. 1.95 under different sintering conditions. JPower Sources 2008, 183:498-505.
25. Mukherjee T., Bedekar V., Patra A., Sastry P.U., Tyagi A.K. Study of agglomeration behavior of combustion-synthesized nano-crystalline ceria using new fuels. JAlloy Compd 2008, 466:493-497.
26. Rey J.F.Q., Muccillo E.N.S. Lattice parameters of yttria-doped ceria solid electrolytes. JEur Ceram Soc 2004, 24:1287-1290.
27. 3+ codoped ceria-based electrolytes for intermediate temperature-solid oxide fuel cell. JPower Sources 2010, 195:2488-2495.
28. Tadokoro S.K., Porfírio T.C., Muccillo R., Muccillo E.N.S. Synthesis, sintering and impedance spectroscopy of 8mol% yttria-doped ceria solid electrolyte. JPower Sources 2004, 130:15-21.
29. 3-x nanopowders for solid oxide fuel cell cathodes. JPower Sources 2006, 158:148-153.
30. Inaba H., Nakajima T., Tagawa H. Sintering behaviors of ceria and gadolinia-doped ceria. Solid State Ionics 1998, 106:263-268.
31. Cullity B.D. Elements of X-ray diffraction 1978, Addison-Wesley, Reading, MA.
32. 3+. JPower Sources 2010, 195:969-976.
33. Hui S., Roller J., Yick S., Zhang X., Decès-Petit C., Xie Y., et al. Abrief review of the ionic conductivity enhancement for selected oxide electrolytes. JPower Sources 2007, 172:493-502.
34. Maca K., Cihlar J., Castkova K., Zmeskal O., Hadraba H. Sintering of gadolinia-doped ceria prepared by mechanochemical synthesis. JEur Ceram Soc 2007, 27:4345-4348.
35. Kosinski M.R., Baker R.T. Preparation and property-performance relationships in samarium-doped ceria nanopowders for solid oxide fuel cell electrolytes. JPower Sources 2011, 196:2498-2512.
36. Zhao F., Virkar A.V. Effect of morphology and space charge on conduction through porous doped ceria. JPower Sources 2010, 195:6268-6279.
37. 3+ co-doped ceria electrolyte. JAm Ceram Soc 2008, 91:3926-3930.
38. 3-δ (0 ≤ x = y ≤ 0.08). Solid State Commun 2008, 145:132-136.
39. 2-y solid solution. JAlloy Compd 2003, 349:273-278.
40. 3 electrolyte material. Solid State Ionics 1996, 91:249-256.
41. Huijsmans J.P.P., van Berkel F.P.F., Christie G.M. Intermediate temperature SOFC - a promise for the 21st century. JPower Sources 1998, 71:107-110.