Steam reforming of iso-octane toward hydrogen production over mono- And bi-metallic CueCo/ CeO2 catalysts: Structure-activity correlations

International Journal of Hydrogen Energy

Volumn 39, Issue 34, 2014, Pages 19541-19554

  Al Musa, A A ^a   Ioakeimidis, Z S ^b   Al Saleh, M S ^a   Al Zahrany, A ^a   Marnellos, G E ^b,c   Konsolakis, M ^d  

^a King Abdulaziz City for Science and Technology Energy Research Institute   (Saudi Arabia)

^b UNIVERSITY OF WESTERN MACEDONIA   (Greece)

^c INFORMATION TECHNOLOGIES INSTITUTE   (Greece)

^d TECHNICAL UNIVERSITY OF CRETE   (Greece)

Author keywords

[No Author keywords available]

Indexed keywords

C (PROGRAMMING LANGUAGE); CARBON; CATALYST ACTIVITY; CATALYST DEACTIVATION; HYDROGEN PRODUCTION; MESOPOROUS MATERIALS; METALS; POLYOLS; SCANNING ELECTRON MICROSCOPY; SINTERING; STEAM; TEMPERATURE PROGRAMMED DESORPTION; X RAY DIFFRACTION; X RAY PHOTOELECTRON SPECTROSCOPY;

ADSORPTION DESORPTION; BIMETALLIC CATALYSTS; CHARACTERIZATION STUDIES; ISO-OCTANE; LONG-TERM STABILITY TEST; STRUCTURE-ACTIVITY CORRELATIONS; TEMPERATURE INTERVALS; TEMPERATURE-PROGRAMMED REDUCTION;

STEAM REFORMING;

EID: 84922621293     PISSN: 03603199     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.ijhydene.2014.09.107     Document Type: Article

References (72)

1. Hoogers G. Fuel cell technology handbook. CRC Press; 2003.
2. Singhal SC, Kendall K. High temperature solid oxide fuel cells: fundamentals, design and applications. Elsevier Advanced Technology; 2003.
3. Marnellos GE, Athanasiou C, Makridis SS, Kikkinides ES. Integration of hydrogen energy technologies in autonomous power systems. In: Zoulias EI, Lymberopoulos N, editors. Hydrogen based autonomous power systems. Springer Eds; 2008 [Chapter 3].
4. Katzer JR, Ramage MP, Sapre AV. Petroleum refining: poised for profound changes. Chem Eng Prog 2000;96(7):41-51.
5. Gorte RJ, Kim H, Vohs JM. Novel SOFC anodes for the direct electrochemical oxidation of hydrocarbon. J Power Sources 2002;106(1-2):10-5.
6. Gorte RJ, Vohs JM, McIntosh S. Recent developments on anodes for direct fuel utilization in SOFC. Solid State Ionics 2004;175(1-4):1-6.
7. Takeichi N, Senoh H, Yokota T, Tsuruta H, Hamada K, Takeshita HT, et al. "Hybrid hydrogen storage vessel", a novel high-pressure hydrogen storage vessel combined with hydrogen storage material. Int J Hydrogen Energy 2003;28(10):1121-9.
8. Sakintuna B, Lamari-Darkrim F, Hirscher M. Metal hydride materials for solid hydrogen storage: A review. Int J Hydrogen Energy 2007;32(9):1121-40.
9. Saunders GJ, Kendall K. Reactions of hydrocarbons in small tubular SOFCs. J Power Sources 2002;106(1-2):258-63.
10. Ahmed S, Krumpelt M. Hydrogen from hydrocarbon fuels for fuel cells. Int J Hydrogen Energy 2001;26(4):291-301.
11. 2C for iso-octane steam reforming. Catal Today 2008;136(3-4):235-42.
12. Qi A, Wang S, Ni C, Wub D. Autothermal reforming of gasoline on Rh-based monolithic catalysts. Int J Hydrogen Energy 2007;32:981-91.
13. Avci AK, Önsan ZI, Trimm DT. On-board fuel conversion for hydrogen fuel cells: comparison of different fuels by computer simulations. Appl Catal A Gen 2001;216(1-2):243-56.
14. Biniwale RB, Ichikawa NKM. Production of hydrogen-rich gas via reforming of iso-octane over NieMn and RheCe bimetallic catalysts using spray pulsed reactor. Catal Lett 2005;100(1-2):17-25.
15. Gorte RJ, Vohs JM. Novel SOFC anodes for the direct electrochemical oxidation of hydrocarbons. J Catal 2003;216(1-2):477-86.
16. Zhang Z, Barnett SA. Solid oxide fuel cells operated by internal partial oxidation reforming of iso-octane. J Power Sources 2006;155(2):353-7.
17. Zhang Z, Barnett SA. Operation of ceria-electrolyte solid oxide fuel cells on iso octane-air fuel mixtures. J Power Sources 2006;157(1):422-9.
18. Dhir A, Kendall K. Microtubular SOFC anode optimization for direct use on methane. J Power Sources 2008;181(2):297-303.
19. Ding D, Liu Z, Li L, Xia C. An octane-fueled low temperature solid oxide fuel cell with Ru-free anodes. Electrochem Commun 2008;10(9):1295-8.
20. García-Vargas JM, Valverde JL, De Lucas-Consuegra A, Gómez-Monedero B, Dorado F, Sánchez P. Methane trireforming over a Ni/b-SiC-based catalyst: optimizing the feedstock composition. Int J Hydrogen Energy 2013;38(11):4524-32.
21. Angeli SD, Monteleone G, Giaconia A, Lemonidou AA. State-ofthe- Art catalysts for CH4 steam reforming at low temperature: A review. Int J Hydrogen Energy 2014;39(5):1979-97.
22. Brett DJL, Atkinson A, Brandon NP, Skinner SJ. Intermediate temperature solid oxide fuel cells. Chem Soc Rev 2008;37:1568-78.
23. Gaudillere C, Vernoux P, Mirodatos C, Caboche G, Farrusseng D. Screening of ceria-based catalysts for internal methane reforming in low temperature SOFC. Catal Today 2010;157(1-4):263-9.
24. He H, Vohs JM, Gorte RJ. Carbonaceous deposits in direct utilization hydrocarbon SOFC anode. J Power Sources 2005;144(1):135-40.
25. Ormerod RM. Solid oxide fuel cells. Chem Soc Rev 2003;32(1):17-28.
26. Saunders GJ, Preece J, Kendall K. Formulating liquid hydrocarbon fuels for SOFCs. J Power Sources 2004;131(1-2):23-6.
27. 2, CO and syngas. J Power Sources 2005;141(2):241-9.
28. Wu H, La Parola V, Pantaleo G, Puleo F, Venezia AM, Liotta LF. Ni-based catalysts for low temperature methane steam reforming: recent results on NieAu and comparison with other bi-metallic systems. Catalysts 2013;3:563-83.
29. Kaklidis N, Pekridis G, Athanasiou C, Marnellos GE. Direct electro-oxidation of iso-octane in a solid electrolyte fuel cell. Solid State Ionics 2011;192(1):435-43.
30. Zhan Z, Barnet SA. An octane-fueled solid oxide fuel cell. Science 2005;308:844-7.
31. Georges S, Parrour G, Henault M, Fouletier J. Gradual internal reforming of methane: A demonstration. Solid State Ionics 2006;177:2109-12.
32. Liu M, Choi Y, Yang L, Blinn K, Qin W, Liu P, et al. Direct octane fuel cells: A promising power for transportation. Nano Energy 2012;1:448-55.
33. 2 catalysts: redox features and catalytic behaviors. Appl Catal A Gen 2005;288:116-25.
34. Spivey JJ, Dooley KM. Gold catalysis in organic synthesis and material science. Catalysis 2010;22:279-317.
35. 2 catalysts: The effect of the support reducibility and of the metal dispersion on the stability of the catalysts. Catal Today 2005;101(1):23-30.
36. 2 support on reactivity, resistance toward carbon formation, and intrinsic reaction kinetics. Appl Catal A Gen 2005;290(1-2):200-11.
37. 3-δ anodes for direct utilization of methane in SOFC. Solid State Ionics 2007;178:1467-75.
38. 2 YSZ. J Electrochem Soc 2004;151(9):1319-23.
39. Kim H, Lu C, Worrell WL, Vohs JM, Gorte RJ. Cu-Ni cermet anodes for direct oxidation of methane in solid-oxide fuel cells. J Electrochem Soc 2002;149(3):A247-50.
40. De la Piscina RP, Homs N. Use of biofuels to produce hydrogen (reformation processes). Chem Soc Rev 2008;37:2459-67.
41. Song H, Ozkan US. Ethanol steam reforming over Co-based catalysts: role of oxygen mobility. J Catal 2008;261:66-74.
42. 8 (Me = Co, Rh or Co-noble metal). Top Catal 2009;52:2101-7.
43. Finocchio E, Rossetti I, Ramis G. Redox properties of Co- And Cu-based catalysts for the steam reforming of ethanol. Int J Hydrogen Energy 2013;38:3213-25.
44. Cai W, De la Piscina PR, Homsa N. Hydrogen production from the steam reforming of bio-butanol over novel supported Cobased bimetallic catalysts. Bioresour Technol 2012;107:482-6.
45. Al-Musa A, Al-Saleh M, Ioakeimidis ZC, Ouzounidou M, Yentekakis IV, Konsolakis M, et al. Hydrogen production by iso-octane steam reforming over Cu catalysts supported on rare earth oxides (REOs). Int J Hydrogen Energy 2014;39:1350-63.
46. Praharso AA, Adesina DL, Trimm S, Cant NW. Kinetic study of iso-octane steam reforming over a nickel-based catalyst. Chem Eng J 2004;99(2):131-6.
47. Murata K, Wang L, Saito M, Inaba M, Takahara I, Mimura N. Hydrogen production from steam reforming of hydrocarbons over alkaline-earth metal-modified Fe- or Ni-based catalysts. Energy Fuels 2004;18(1):122-6.
48. Sobacchi MG, Saveliev AV, Fridman AA, Kennedy LA, Ahmed S, Krause T. Experimental assessment of a combined plasma/catalytic system for hydrogen production via partial oxidation of hydrocarbon fuels. Int J Hydrogen Energy 2002;27(6):635-42.
49. Wang X, Wang N, Wang L. Hydrogen production by sorption enhanced steam reforming of propane: A thermodynamic investigation. Int J Hydrogen Energy 2011;36(1):466-72.
50. 2-rich stream. Catal Lett 2009;127:377-85.
51. Liu W, Flytzani-Stephanopoulos M. Total oxidation of carbon-monoxide and methane over transition metal fluorite oxide composite catalysts: II. Catalyst characterization and reaction-kinetics. J Catal 1995;153:317-32.
52. Kundakovic L, Flytzani-Stephanopoulos M. Reduction characteristics of copper oxide in cerium and zirconium oxide systems. Appl Catal A Gen 1998;171:13-29.
53. 2 catalysts: correlation between activity and low temperature reducibility. Int J Hydrogen Energy 2012;37:1993-2006.
54. 2 nanocomposite catalysts for the low temperature oxidation of CO. Appl Surf Sci 2011;257:7551-9.
55. x. Catal Today 2013;216:246-53.
56. 2 interaction and catalytic activity. Appl Catal B Environ 2006;66:217-27.
57. 2. Appl Catal B Environ 2003;41:301-12.
58. 3system for hydrocarbon synthesis. Appl Catal A Gen 2001;207:343-53.
59. Konsolakis M, Ioakeimidis Z. Surface/structure functionalization of copper-based catalysts by metal-support and/or metalemetal interactions. Appl Surf Sci 2014. http://dx.doi.org/10.1016/j.apsusc.2014.08.114.
60. 2 catalysts on the steam reforming of ethanol. Int J Hydrogen Energy 2014http://dx.doi.org/10.1016/j.ijhydene.2014.07.139.
61. 2 catalysts in methanol steam reforming. Appl Catal B Environ 2007;69(3-4):226-34.
62. 2 in hydrogen-rich streams: effect of cobalt loading. Appl Catal B Environ 2012;128:21-30.
63. 1.9 catalyst for steam reforming of liquid hydrocarbons in fuel cell applications. J Catal 2008;254:39-48.
64. Swartz SL, Matter PH, Arkenberg GB, Holcomb FH, Josefik NM. Hydrogen production from E85 fuel with ceriabased catalysts. J Power Sources 2009;188:515-20.
65. 2 catalysts in ethanol steam reforming: inhibition of coke formation by CaO-doping. Appl Catal B 2014;150-151:12-20.
66. 2 catalysts for high temperature processes of hydrogen production: steam reforming of ethanol and methane dry re-forming. J Phys Chem A 2010;114(11):3939-49.
67. Vicente J, Montero C, Erena J, Azkoiti MJ, Bilbao J, Gayubo AG. Coke deactivation of Ni and Co catalysts in ethanol steam reforming at mild temperatures in a fluidized bed reactor. Int J Hydrogen Energy 2014;39:12586-96.
68. Mosqueda B, Toyir J, Kaddouri A, Gélin P. Steam reforming of methane under water deficient conditions over gadoliniumdoped ceria. Appl Catal B 2009;88(3-4):361-7.
69. 2 catalysts: A structure sensitivity analysis. J Catal 2012;286:137-52.
70. 3 catalyst promoted with Mn oxides. Appl Catal A Gen 2005;282:73-83.
71. Moon DJ. Hydrogen production by catalytic reforming of liquid hydrocarbons. Catal Sur Asia 2011;15:25-36.
72. 2 for the oxidative steam reforming of ethanol. Catal Today 2011;164:234-9.