Corrigendum to “Dry reforming of methane: Influence of process parameters—A review” [Renew Sustain Energy Rev 45 (2015) 710–744] (Renewable and Sustainable Energy Reviews (2015) 45 (710–744), (S1364032115001148), (10.1016/j.rser.2015.02.026));Dry reforming of methane: Influence of process parameters - A review

Renewable and Sustainable Energy Reviews

Volumn 45, Issue , 2015, Pages 710-744

  Usman, Muhammad ^a   Wan Daud, W M A ^a   Abbas, Hazzim F ^b  

^a UNIVERSITY OF MALAYA   (Malaysia)

^b UNIVERSITY OF NIZWA   (Oman)

Author keywords

Carbon deposition; Dry reforming of methane; Landfill gas; Ni catalyst; Syn gas

Indexed keywords

BARIUM TITANATE; BINARY ALLOYS; BIOREACTORS; CALCINATION; CARBON; CATALYST ACTIVITY; CATALYST SUPPORTS; DEPOSITION; FILM PREPARATION; HYDROGEN PRODUCTION; MAGNESIA; MESOPOROUS MATERIALS; METHANE; MIXTURES; NICKEL; PARTICLE SIZE; ZIRCONIA;

ACTIVE METALS; CALCINATION TEMPERATURE; CARBON DEPOSITION; DRY REFORMING; DRY REFORMING-OF-METHANE; LANDFILL GAS; NI CATALYSTS; PREPARATION METHOD; SMALL PARTICLE SIZE; SYN GAS;

CERIUM OXIDE;

EID: 84923799953     PISSN: 13640321     EISSN: 18790690     Source Type: Journal    
DOI: 10.1016/j.rser.2020.110329     Document Type: Erratum

References (313)

1. X. Li Diversification and localization of energy systems for sustainable development and energy security Energy Policy 33 2005 2237 2243
2. A. Tanksale, J.N. Beltramini, and G.M. Lu A review of catalytic hydrogen production processes from biomass Renew Sustain Energy Rev 14 2010 166 182
3. DOE U International energy outlook 2007. Technical report no. DOE/EIA-0484. 〈http://www.eia.doe.gov/oiaf/ieo/pdf/0484(2007).pdf〉 2007.
4. MEDD Oliveira, and B.E. Vaughan Jr. EJR ethanol as fuel: energy, carbon dioxide balances, and ecological footprint Bioscience 55 2005 593 602
5. Z.Z. Noor, R.O. Yusuf, A.H. Abba, M.A. Abu Hassan, and M.F. Mohd Din An overview for energy recovery from municipal solid wastes (MSW) in Malaysia scenario Renew Sustain Energy Rev 20 2013 378 384
6. J.J. McCarthy, O.F. Canziani, N.A. Leary, D.J. Dokken, and K.S. White Climate change 2001: impacts, adaptation, and vulnerability: contribution of working group II to the third assessment report of the Intergovernmental Panel on Climate Change 2001 Cambridge University Press UK
7. F. Montagnini, and P. Nair Carbon sequestration: an underexploited environmental benefit of agroforestry systems Agroforest Syst 61 2004 281 295
8. M.L. Parry Climate change 2007: impacts, adaptation and vulnerability: working group I contribution to the fourth assessment report of the IPCC 2007 Cambridge University Press UK
9. Tarasova O, Koide H, Dlugokencky E, Montzka SA, Griffith D, Brunke E, et al. The state of greenhouse gases in the atmosphere using global observations through 2011. In: Proceedings of EGU general assembly conference abstracts; 2013. p. 2799.
10. V. Talyan, R. Dahiya, S. Anand, and T. Sreekrishnan Quantification of methane emission from municipal solid waste disposal in Delhi Resour, Conserv Recycl 50 2007 240 259
11. K. Warmuzinski Harnessing methane emissions from coal mining Proc Saf Environ Prot 86 2008 315 320
12. D.J. Wuebbles, and K. Hayhoe Atmospheric methane and global change Earth-Sci Rev. 57 2002 177 210
13. 2 and CO Atmos Chem Phys Discuss 13 2013 23549 23598
14. R.O. Yusuf, Z.Z. Noor, A.H. Abba, M.A.A. Hassan, and M.F.M. Din Methane emission by sectors: a comprehensive review of emission sources and mitigation methods Renew Sustain Energy Rev 16 2012 5059 5070
15. A. Johari, S.I. Ahmed, H. Hashim, H. Alkali, and M. Ramli Economic and environmental benefits of landfill gas from municipal solid waste in Malaysia Renew Sustain Energy Rev 16 2012 2907 2912
16. G. Karavalakis, T.D. Durbin, M. Villela, and J.W. Miller Air pollutant emissions of light-duty vehicles operating on various natural gas compositions J Nat Gas Sci Eng 4 2012 8 16
17. J.H. Lunsford Catalytic conversion of methane to more useful chemicals and fuels: a challenge for the 21st century Catal Today 63 2000 165 174
18. Global gas flaring reduction public-private partnership (GGFR). Estimated flared volumes from satellite data, 2007-2011; 2011.
19. C. Elvidge, D. Ziskin, K. Baugh, B. Tuttle, T. Ghosh, and D. Pack A fifteen year record of global natural gas flaring derived from satellite data Energies 2 2009 595 622
20. D. Hoornweg, and P. Bhada-Tata What a waste: a global review of solid waste management 2012 World Bank Washington DC
21. D. Suocheng, K.W. Tong, and W. Yuping Municipal solid waste management in China: using commercial management to solve a growing problem Utilities Policy 10 2001 7 11
22. M.F. Abushammala, N.E.A. Basri, H. Basri, A.H. El-Shafie, and A.A.H. Kadhum Regional landfills methane emission inventory in Malaysia Waste Manag Res 29 2011 863 873
23. A. EPA Inventory of US greenhouse gas emissions and sinks: 1990-2009 430-R-11-005 2011 EPA
24. B. Raco, R. Battaglini, and M. Lelli Gas emission into the atmosphere from controlled landfills: an example from Legoli landfill (Tuscany, Italy) Environ Sci Pollut Res 17 2010 1197 1206
25. Wang-Yao K, Towprayoon S, Chiemchaisri C, Gheewala SH, Nopharatana A. Seasonal variation of landfill methane emission from seven solid waste disposal sites in central Thailand. In: Proceedings of the 2nd joint international conference on sustainable energy and environment (SEE 2006). Thailand; 2006. p. 1-4.
26. 4 Catal Rev 41 1999 1 42
27. J.B. Claridge, A.P.E. York, A.J. Brungs, C. Marquez-Alvarez, J. Sloan, and S.C. Tsang New catalysts for the conversion of methane to synthesis gas: molybdenum and tungsten carbide J Catal 180 1998 85 100
28. D. Li, Y. Nakagawa, and K. Tomishige Methane reforming to synthesis gas over Ni catalysts modified with noble metals Appl Catal A Gen 408 2011 1 24
29. J.R. Rostrup-Nielsen Production of synthesis gas Catal Today 18 1993 305 324
30. M.A. Pena, J.P. Gómez, and J.L.G. Fierro New catalytic routes for syngas and hydrogen production Appl Catal A Gen 144 1996 7 57
31. 2 catalyst: effect of nickel content Fuel Process Technol 106 2013 247 252
32. P. Djinović, I.G. Osojnik Črnivec, B. Erjavec, and A. Pintar Influence of active metal loading and oxygen mobility on coke-free dry reforming of Ni-Co bimetallic catalysts Appl Catal B Environ 125 2012 259 270
33. D.J. Wilhelm, D.R. Simbeck, A.D. Karp, and R.L. Dickenson Syngas production for gas-to-liquids applications: technologies, issues and outlook Fuel Process Technol 71 2001 139 148
34. P. Gangadharan, K.C. Kanchi, and H.H. Lou Evaluation of the economic and environmental impact of combining dry reforming with steam reforming of methane Chem Eng Res Des 90 2012 1956 1968
35. S.T. Oyama, P. Hacarlioglu, Y. Gu, and D. Lee Dry reforming of methane has no future for hydrogen production: comparison with steam reforming at high pressure in standard and membrane reactors Int J Hydrog Energy 37 2012 10444 10450
36. 2) for methanol and hydrocarbon synthesis J Am Chem Soc 135 2012 648 650
37. M.A. Nieva, M.M. Villaverde, A. Monzón, T.F. Garetto, and A.J. Marchi Steam-methane reforming at low temperature on nickel-based catalysts Chem Eng J 235 2014 158 166
38. 3 catalysts for methane steam reforming Catal Today 142 2009 52 60
39. A.S. Larimi, and S.M. Alavi Ceria-zirconia supported Ni catalysts for partial oxidation of methane to synthesis gas Fuel 102 2012 366 371
40. E. Ruckenstein, and H.u.Y. Hang Methane partial oxidation over NiO/MgO solid solution catalysts Appl Catal A Gen 183 1999 85 92
41. A.F. Lucredio, J.M. Assaf, and E.M. Assaf Reforming of a model biogas on Ni and Rh-Ni catalysts: effect of adding La Fuel Process Technol 102 2012 124 131
42. M.P. Kohn, M.J. Castaldi, and R.J. Farrauto Biogas reforming for syngas production: the effect of methyl chloride Appl Catal B Environ 144 2014 353 361
43. 2 reforming in a fluidized-bed reactor Chem Eng Sci 55 2000 3955 3966
44. M. Levy, R. Levitan, E. Meirovitch, A. Segal, H. Rosin, and R. Rubin Chemical reactions in a solar furnace 2: direct heating of a vertical reactor in an insulated receiver. Experiments and computer simulations Sol Energy 48 1992 395 402
45. 4 reforming-methanation cycle relevant to the solchem thermochemical power system Sol Energy 24 1980 341 345
46. 4 (1: 1) system Int J Hydrog Energy 11 1986 267 277
47. J. Edwards, and A. Maitra The chemistry of methane reforming with carbon dioxide and its current and potential applications Fuel Process Technol 42 1995 269 289
48. S. Tsang, J. Claridge, and M. Green Recent advances in the conversion of methane to synthesis gas Catal Today 23 1995 3 15
49. J. Zhang, H. Wang, and A.K. Dalai Development of stable bimetallic catalysts for carbon dioxide reforming of methane J Catal 249 2007 300 310
50. 2 reforming of methane Int J Hydrog Energy 38 2013 2230 2239
51. 2 Chem Eng Sci 43 1988 3049 3062
52. Z.L. Zhang, and X.E. Verykios Carbon dioxide reforming of methane to synthesis gas over supported Ni catalysts Catal Today 21 1994 589 595
53. 2 reforming reaction Appl Catal A Gen 161 1997 L11 L17
54. 3 in fixed/fluidized-bed multi-switching mode Appl Catal A Gen 279 2005 263 271
55. 2 catalysts for ethanol steam reforming Chem Eng J. 163 2010 395 402
56. D. Liu, X.Y. Quek, W.N.E. Cheo, R. Lau, A. Borgna, and Y. Yang MCM-41 supported nickel-based bimetallic catalysts with superior stability during carbon dioxide reforming of methane: effect of strong metal-support interaction J Catal 266 2009 380 390
57. 2 catalysts Chem Eng Process Process Intensif 50 2011 1054 1062
58. Z. Hou, P. Chen, H. Fang, X. Zheng, and T. Yashima Production of synthesis gas via methane reforming with CO on noble metals and small amount of noble-(Rh-) promoted Ni catalysts Int J Hydrog Energy 31 2006 555 561
59. A.I. Tsyganok, M. Inaba, T. Tsunoda, S. Hamakawa, K. Suzuki, and T. Hayakawa Dry reforming of methane over supported noble metals: a novel approach to preparing catalysts Catal Commun 4 2003 493 498
60. 2 reforming of methane Appl Catal A Gen 225 2002 1 9
61. 2-reforming of methane over transition metals J Catal 144 1993 38 49
62. 2) reforming. fuel cells: technologies for fuel processing 2011 Elsevier 191 221
63. 3 catalysts for methane dry reforming Catal Today 172 2011 226 231
64. M. García-Diéguez, E. Finocchio, M.Á. Larrubia, L.J. Alemany, and G. Busca Characterization of alumina-supported Pt, Ni and PtNi alloy catalysts for the dry reforming of methane J Catal 274 2010 11 20
65. 2: Preparation, characterization and activity studies Appl Catal B Environ 100 2010 365 377
66. 2 supported Ni-Rh catalysts Appl Catal A Gen 280 2005 233 244
67. 2 Appl Catal A Gen 323 2007 188 201
68. B. Steinhauer, M.R. Kasireddy, J. Radnik, and A. Martin Development of Ni-Pd bimetallic catalysts for the utilization of carbon dioxide and methane by dry reforming Appl Catal A Gen 366 2009 333 341
69. 2 on CeZr-oxide supported Ni, NiRh and NiCo catalysts prepared by sol-gel technique: relationship between activity and coke formation Catal Today 169 2011 102 111
70. T. Huang, W. Huang, J. Huang, and P. Ji Methane reforming reaction with carbon dioxide over SBA-15 supported Ni-Mo bimetallic catalysts Fuel Process Technol 92 2011 1868 1875
71. D. Liu, W.N.E. Cheo, Y.W.Y. Lim, A. Borgna, R. Lau, and Y. Yang A comparative study on catalyst deactivation of nickel and cobalt incorporated MCM-41 catalysts modified by platinum in methane reforming with carbon dioxide Catal Today 154 2010 229 236
72. 2 reforming in a fluidized bed Fuel Process Technol 90 2009 113 121
73. 2 reforming Powder Technol 183 2008 46 52
74. M.M. Barroso-Quiroga, and A.E. Castro-Luna Catalytic activity and effect of modifiers on Ni-based catalysts for the dry reforming of methane Int J Hydrog Energy 35 2010 6052 6056
75. J.-S. Chang, D.-Y. Hong, X. Li, and S.-E. Park Thermogravimetric analyses and catalytic behaviors of zirconia-supported nickel catalysts for carbon dioxide reforming of methane Catal Today 115 2006 186 190
76. M. Rezaei, S.M. Alavi, S. Sahebdelfar, and Z.-F. Yan A highly stable catalyst in methane reforming with carbon dioxide Scr Mater 61 2009 173 176
77. 2 Int J Hydrog Energy 34 2009 9711 9722
78. H.Y. Wang, and E. Ruckenstein Carbon dioxide reforming of methane to synthesis gas over supported rhodium catalysts: the effect of support Appl Catal A Gen 204 2000 143 152
79. 2 on Pt-supported catalysts Catal Today 107-108 2005 481 486
80. 2 over the NiO/MgO catalyst Fuel 109 2012 110 115
81. 4 over Co/MgO solid solution catalysts - effect of calcination temperature and Co loading Appl Catal A Gen 209 2001 207 215
82. 2 using fluidized bed reactor Energy Convers Manag 45 2004 3127 3137
83. 2/MgO catalysts: modification of support using ion exchange resin method J Na Gas Chem 21 2012 76 82
84. A. Pietraszek, B. Koubaissy, A.-C. Roger, and A. Kiennemann The influence of the support modification over Ni-based catalysts for dry reforming of methane reaction Catal Today 176 2011 267 271
85. Y. Makhum Ni-Rh catalysts on cerium zirconyl oxide for dry reforming of methane 2006 Chulalongkorn University Thailand
86. 2 reforming Fuel 87 2008 2901 2907
87. 4 Int J Hydrog Energy 38 2013 4508 4512
88. M. Safariamin, L.H. Tidahy, E. Abi-Aad, S. Siffert, and A. Aboukaïs Dry reforming of methane in the presence of ruthenium-based catalysts Comptes Rendus Chim 12 2009 748 753
89. D. Liu, R. Lau, A. Borgna, and Y. Yang Carbon dioxide reforming of methane to synthesis gas over Ni-MCM-41 catalysts Appl Catal A Gen 358 2009 110 118
90. H. Arbag, S. Yasyerli, N. Yasyerli, and G. Dogu Activity and stability enhancement of Ni-MCM-41 catalysts by Rh incorporation for hydrogen from dry reforming of methane Int J Hydrog Energy 35 2010 2296 2304
91. S. Yasyerli, S. Filizgok, H. Arbag, N. Yasyerli, and G. Dogu Ru incorporated Ni-MCM-41 mesoporous catalysts for dry reforming of methane: effects of Mg addition, feed composition and temperature Int J Hydrog Energy 36 2011 4863 4874
92. 2 Chin J Catal 27 2006 777 781
93. 3 catalyst: its characterization and catalytic performance J Nat Gas Chem 20 2011 465 470
94. 2 using fixed- and fluidised-bed reactors Catal Commun 4 2003 203 207
95. 2 catalyst: the effect of calcination ambience Int J Hydrog Energy 38 2013 117 126
96. 3 perovskite (M=Bi, Co, Cr, Cu, Fe): roles of lattice oxygen on C-H activation and carbon suppression Int J Hydrog Energy 37 2012 11195 11207
97. 2 over activated carbon based catalysts Appl Catal A Gen 469 2014 387 397
98. S. Barama, C. Dupeyrat-Batiot, M. Capron, E. Bordes-Richard, and O. Bakhti-Mohammedi Catalytic properties of Rh, Ni, Pd and Ce supported on Al-pillared montmorillonites in dry reforming of methane Catal Today 141 2009 385 392
99. 2 Appl Catal A Gen 316 2007 175 183
100. K. Takanabe, K. Nagaoka, K. Nariai, and K.-i. Aika Titania-supported cobalt and nickel bimetallic catalysts for carbon dioxide reforming of methane J Catal 232 2005 268 275
101. J. Xu, W. Zhou, Z. Li, J. Wang, and J. Ma Biogas reforming for hydrogen production over nickel and cobalt bimetallic catalysts Int J Hydrog Energy 34 2009 6646 6654
102. 2 reforming of methane Top Catal 53 2010 265 272
103. 2 Chem Eng J 148 2009 539 545
104. S.M. de Lima, and J.M. Assaf Ni-Fe catalysts based on perovskite-type oxides for dry reforming of methane to syngas Catal Lett 108 2006 63 70
105. 2: a study on surface carbon species Appl Catal A Gen 375 2010 236 246
106. 2 catalysts Appl Organomet Chem 15 2001 109 112
107. 2 reforming of methane: activity and metal-support interaction J Mol Catal A Chem 299 2009 44 52
108. A.F. Lucrédio, J.M. Assaf, and E.M. Assaf Methane conversion reactions on Ni catalysts promoted with Rh: influence of support Appl Catal A Gen 400 2011 156 165
109. i J Mol Catal A Chem 198 2003 263 275
110. X. Zhu, Y. Wei, H. Wang, and K. Li Ce-Fe oxygen carriers for chemical-looping steam methane reforming Int J Hydrog Energy 38 2013 4492 4501
111. 2 reforming of methane by dielectric-barrier discharge plasma Catal Commun 11 2010 968 972
112. 3 catalysts Catal Today 171 2011 132 139
113. 4 reforming Chem Eng J 207-208 2012 299 307
114. 2 to syngas Int J Hydrog Energy 38 2013 1892 1900
115. 3 catalyst performance in methane dry reforming Chin J Catal 32 2011 1604 1609
116. G. Mul, and J.A. Moulijn Preparation of supported metal catalysts Catal Sci Ser 5 2005 1 32
117. 3 catalyst Appl Catal A Gen 205 2001 31 36
118. 2/CO ratio and carbon deposition Int J Hydrog Energy 35 2010 12147 12160
119. Y.H. Hu, and E. Ruckenstein Binary MgO-based solid solution catalysts for methane conversion to syngas Catal Rev 44 2002 423 453
120. 2 catalysts for the dry reforming of methane Appl Catal A Gen 377 2010 16 26
121. 2 catalyst for dry reforming of methane Catal Commun 31 2013 25 31
122. 2 reforming Appl Catal B: Environ 136 2013 260 268
123. 4 over nanocrystalline zirconia-supported nickel catalysts Appl Catal B Environ 77 2008 346 354
124. 2 catalyst in a packed bed tubular reactor Chem Eng Sci 62 2007 4012 4024
125. 2 J Catal 197 2001 34 42
126. 2 solid solution Microporous Mesoporous Mater 143 2011 357 361
127. 2 as catalysts for the partial oxidation of methane Catal Today 142 2009 308 313
128. M.C. Bradford, and M.A. Vannice Catalytic reforming of methane with carbon dioxide over nickel catalysts I. Catalyst characterization and activity Appl Catal A Gen 142 1996 73 96
129. 2 over supported Ni catalysts J Catal 219 2003 176 185
130. 2-Ni inverse catalyst Appl Catal A Gen 451 2013 43 49
131. C. Kresge, M. Leonowicz, W. Roth, J. Vartuli, and J. Beck Ordered mesoporous molecular sieves synthesized by a liquid-crystal template mechanism Nature 359 1992 710 712
132. 2S removal Ind Eng Chem Res 47 2008 1035 1042
133. C. Sener, T. Dogu, and G. Dogu Effects of synthesis conditions on the structure of Pd incorporated MCM-41 type mesoporous nanocomposite catalytic materials with high Pd/Si ratios Microporous Mesoporous Mater 94 2006 89 98
134. 2 addition Fuel Process Technol 89 2008 160 168
135. 3 catalysts under fixed- and fluidized-bed operations Appl Catal A Gen 288 2005 86 97
136. S.K. Saraswat, and K.K. Pant Ni-Cu-Zn/MCM-22 catalysts for simultaneous production of hydrogen and multiwall carbon nanotubes via thermo-catalytic decomposition of methane Int J Hydrog Energy 36 2011 13352 13360
137. 4 J Ind Eng Chem 19 2013 1566 1576
138. 2 catalyst Int J Hydrog Energy 37 2012 2699 2707
139. L. Xiancai, W. Min, L. Zhihua, and H. Fei Studies on nickel-based catalysts for carbon dioxide reforming of methane Appl Catal A Gen 290 2005 81 86
140. 3-CaO catalyst prepared by a sol-gel technique Catal Commun 8 2007 661 667
141. 2 over Ni nanoparticle supported on mesoporous ZSM-5 Catal Today. 198 2012 209 214
142. P. Frontera, A. Macario, A. Aloise, P. Antonucci, G. Giordano, and J. Nagy Effect of support surface on methane dry-reforming catalyst preparation Catal Today 218 2013 18 29
143. 2 catalysts for the dry reforming of methane to give synthesis gas Catal Today 178 2011 132 136
144. R. Zanganeh, M. Rezaei, and A. Zamaniyan Dry reforming of methane to synthesis gas on NiO-MgO nanocrystalline solid solution catalysts Int J Hydrog Energy 38 2013 3012 3018
145. V.Y. Bychkov, Y.P. Tyulenin, A.A. Firsova, E.A. Shafranovsky, A.Y. Gorenberg, and V.N. Korchak Carbonization of nickel catalysts and its effect on methane dry reforming Appl Catal A Gen 453 2013 71 79
146. P. Ferreira-Aparicio, M. Fernandez-Garcia, A. Guerrero-Ruiz, and I. RodrI, Íguez-Ramos Evaluation of the role of the metal-support interfacial centers in the dry reforming of methane on alumina-supported rhodium catalysts J Catal 190 2000 296 308
147. 3 Catalysts J Catal 204 2001 498 511
148. 3 ratios J Nat Gas Chem 21 2012 178 183
149. A.A. Lemonidou, M.A. Goula, and I.A. Vasalos Carbon dioxide reforming of methane over 5 wt% nickel calcium aluminate catalysts - effect of preparation method Catal Today 46 1998 175 183
150. S. Wang, K. Murata, T. Hayakawa, S. Hamakawa, and K. Suzuki Selective oxidation of ethane and propane over sulfated zirconia-supported nickel oxide catalysts J Chem Technol Biotechnol 76 2001 265 272
151. 2 composites Fuel 87 2008 2477 2481
152. 2 support composition on nickel catalyst evaluated in dry reforming of methane Appl Catal A Gen 352 2009 179 187
153. 2 nanocrystals by citrate sol-gel method J Alloys Compd 460 2008 565 569
154. 2 and on its catalytic activity in carbon dioxide reforming of methane Catal Commun 11 2009 240 246
155. 2 catalysts Fuel Process Technol 83 2003 147 161
156. M. Fathi, E. Bjorgum, T. Viig, and O. Rokstad Partial oxidation of methane to synthesis gas:: elimination of gas phase oxygen Catal Today 63 2000 489 497
157. J. Lercher, J. Bitter, W. Hally, W. Niessen, and K. Seshan Design of stable catalysts for methane-carbon dioxide reforming Stud Surf Sci Catal. 101 1996 463 472
158. 4 J Catal 178 1998 137 145
159. 4 over supported Pt catalysts J Catal 173 1998 157 171
160. 2 catalysts - effect of zirconia to silica ratio Appl Catal A Gen 389 2010 92 100
161. L. Xu, H. Zhao, H. Song, and L. Chou Ordered mesoporous alumina supported nickel based catalysts for carbon dioxide reforming of methane Int J Hydrog Energy 37 2012 7497 7511
162. M.E. Davis Ordered porous materials for emerging applications Nature 417 2002 813 821
163. 3 Catal Today 133 2008 142 148
164. 4 over Co-La-based perovskite-type catalyst precursors J Power Sources 234 2013 31 37
165. 4 Stud Surf Sci Catal 119 1998 783 788
166. L. Marchetti, and L. Forni Catalytic combustion of methane over perovskites Appl Catal B Environ 15 1998 179 187
167. N. Wang, W. Chu, T. Zhang, and X.S. Zhao Synthesis, characterization and catalytic performances of Ce-SBA-15 supported nickel catalysts for methane dry reforming to hydrogen and syngas Int J Hydrog Energy 37 2012 19 30
168. 4 Catal Today 50 1999 87 96
169. 2 over Rh catalysts Catal Lett 25 1994 265 270
170. A. Brungs, A.E. York, J. Claridge, C. Márquez-Alvarez, and M.H. Green Dry reforming of methane to synthesis gas over supported molybdenum carbide catalysts Catal Letters 70 2000 117 122
171. M. Campanati, G. Fornasari, and A. Vaccari Fundamentals in the preparation of heterogeneous catalysts Catal Today 77 2003 299 314
172. H. Jeong, K.I. Kim, D. Kim, and I.K. Song Effect of promoters in the methane reforming with carbon dioxide to synthesis gas over Ni/HY catalysts J Mol Catal A Chem 246 2006 43 48
173. 2 reforming of methane Catal Today 176 2011 187 190
174. A.P.E. York, T. Suhartanto, and M.L.H. Green Influence of molybdenum and tungsten dopants on nickel catalysts for the dry reforming of methane with carbon dioxide to synthesis gas A. Parmaliana, Studies in Surface Science and Catalysis 1998 Elsevier 777 782
175. C.E. Daza, J. Gallego, F. Mondragón, S. Moreno, and R. Molina High stability of Ce-promoted Ni/Mg-Al catalysts derived from hydrotalcites in dry reforming of methane Fuel 89 2010 592 603
176. 3 catalyst Appl Catal A Gen 343 2008 10 15
177. 1-xO (111) platelet catalyst derived from solvothermal synthesis Appl Catal B Environ 148 2014 177 190
178. C. Shi, and P. Zhang Effect of a second metal (Y, K, Ca, Mn or Cu) addition on the carbon dioxide reforming of methane over nanostructured palladium catalysts Appl Catal B Environ 115-116 2012 190 200
179. B. Huang, X. Li, S. Ji, B. Lang, F. Habimana, and C. Li Effect of MgO promoter on Ni-based SBA-15 catalysts for combined steam and carbon dioxide reforming of methane J Nat Gas Chem 17 2008 225 231
180. 2 reforming to synthesis gas Int J Hydrog Energy 37 2012 9994 10001
181. 2-Ni/Mo/SBA-15 catalysts for carbon dioxide reforming of methane Chin J Catal. 33 2012 637 644
182. 3 catalysts Mater Lett 56 2002 698 704
183. Y. Schuurman, C. Mirodatos, P. Ferreira-Aparicio, I. Rodríguez-Ramos, and A. Guerrero-Ruiz Bifunctional pathways in the carbon dioxide reforming of methane over MgO-promoted Ru/C catalysts Catal Lett 66 2000 33 37
184. 3 formation and its role on activity Int J Hydrog Energy 38 2013 6027 6032
185. 2 catalysts promoted with La and Ce oxides J Catal 194 2000 240 249
186. 3 catalysts for the dry reforming of methane Appl Catal A Gen 301 2006 9 15
187. 4 reforming Int J Hydrog Energy 39 2014 10927 10940
188. 2 Fuel 122 2014 47 53
189. F. Menegazzo, M. Signoretto, F. Pinna, P. Canton, and N. Pernicone Optimization of bimetallic dry reforming catalysts by temperature programmed reaction Appl Catal A Gen 439-440 2012 80 87
190. 4 Int J Hydrog Energy 38 2013 13649 13654
191. 3 treated with glow discharge plasma Catal Today 115 2006 205 210
192. 3 catalyst prepared by dielectric barrier discharge hydrogen plasma Int J Hydrog Energy 39 2014 5756 5763
193. 2 reforming of methane Appl Catal B Environ 81 2008 132 140
194. K.-M. Kang, H.-W. Kim, I.-W. Shim, and H.-Y. Kwak Catalytic test of supported Ni catalysts with core/shell structure for dry reforming of methane Fuel Process Technol 92 2011 1236 1243
195. 4 Appl Catal A Gen 241 2003 349 361
196. 2 reforming reaction ACS Catal 4 2014 1526 1536
197. 2 alloy nanocomposites for methane dry reforming catalysis RSC Adv 3 2013 23976 23979
198. 4 in the dielectric barrier discharge plasma Int J Hydrog Energy 39 2014 11360 11367
199. 3 catalysts. Preprints of Papers - American Chemical Society, Division of Fuel Chemistry, vol. 49; 2004 p.188.
200. R. Garvie, and M. Goss Intrinsic size dependence of the phase transformation temperature in zirconia microcrystals J Mater Sci 21 1986 1253 1257
201. R. Garvie Stabilization of the tetragonal structure in zirconia microcrystals J Phys Chem 82 1978 218 224
202. G. Li, L. Hu, and J.M. Hill Comparison of reducibility and stability of alumina-supported Ni catalysts prepared by impregnation and co-precipitation Appl Catal A Gen 301 2006 16 24
203. 2 catalyst for partial oxidation of methane Fuel 84 2005 563 567
204. H.-W. Kim, K.-M. Kang, H.-Y. Kwak, and J.H. Kim Preparation of supported Ni catalysts on various metal oxides with core/shell structures and their tests for the steam reforming of methane Chem Eng J 168 2011 775 783
205. Q. Ma, D. Wang, M. Wu, T. Zhao, Y. Yoneyama, and N. Tsubaki Effect of catalytic site position: Nickel nanocatalyst selectively loaded inside or outside carbon nanotubes for methane dry reforming Fuel 108 2012 430 438
206. S. Eriksson, U. Nylén, S. Rojas, and M. Boutonnet Preparation of catalysts from microemulsions and their applications in heterogeneous catalysis Appl Catal A Gen 265 2004 207 219
207. D.-H. Chen, and S.-H. Wu Synthesis of nickel nanoparticles in water-in-oil microemulsions Chem Mater 12 2000 1354 1360
208. M. Boutonnet, S. Lögdberg, and E. Elm Svensson Recent developments in the application of nanoparticles prepared from w/o microemulsions in heterogeneous catalysis Curr Opin Colloid Interface Sci 13 2008 270 286
209. 2 catalysts for carbon dioxide reforming of methane. In: Proceedings of 9th internation conference on fracture & strength of solids. Korea; 2013. p. 1-4.
210. J. Liu, S.Z. Qiao, J.S. Chen, X.W.D. Lou, X. Xing, and G.Q.M. Lu Yolk/shell nanoparticles: new platforms for nanoreactors, drug delivery and lithium-ion batteries Chem Commun 47 2011 12578 12591
211. 2 nanotube particles in a water-in-oil microemulsion template Chem Mater 24 2012 2635 2644
212. Q. Yang, D. Han, H. Yang, and C. Li Asymmetric catalysis with metal complexes in nanoreactors Chem Asian J 3 2008 1214 1229
213. 2 yolk-shell nanoreactor catalysts: high temperature stability and recyclability J Mater Chem 20 2010 1239 1246
214. L. Li, P. Lu, Y. Yao, and W. Ji Silica-encapsulated bimetallic Co-Ni nanoparticles as novel catalysts for partial oxidation of methane to syngas Catal Commun 26 2012 72 77
215. L. Li, S. He, Y. Song, J. Zhao, W. Ji, and C.-T. Au Fine-tunable Ni@porous silica core-shell nanocatalysts: synthesis, characterization, and catalytic properties in partial oxidation of methane to syngas J Catal 288 2012 54 64
216. S. Takenaka, H. Umebayashi, E. Tanabe, H. Matsune, and M. Kishida Specific performance of silica-coated Ni catalysts for the partial oxidation of methane to synthesis gas J Catal 245 2007 392 400
217. S. Takenaka, Y. Orita, H. Umebayashi, H. Matsune, and M. Kishida High resistance to carbon deposition of silica-coated Ni catalysts in propane stream reforming Appl Catal A Gen 351 2008 189 194
218. J.M. Montero, P. Gai, K. Wilson, and A.F. Lee Structure-sensitive biodiesel synthesis over MgO nanocrystals Green Chem 11 2009 265 268
219. S.K. Shaikhutdinov, L. Avdeeva, O. Goncharova, D. Kochubey, B. Novgorodov, and L. Plyasova Coprecipitated Ni-Al and Ni-Cu-Al catalysts for methane decomposition and carbon deposition I. Genesis of Calcined and reduced catalysts Appl Catal A Gen 126 1995 125 139
220. Y. Chen, and L. Zhang Surface interaction model of γ-alumina-supported metal oxides Catal Lett 12 1992 51 62
221. 4 spinels. Study of their reducibility Chem Mater 12 2000 331 335
222. 3 catalyst and the corresponding catalytic activity in methane decomposition to hydrogen and carbon nanofibers Appl Catal A Gen 362 2009 1 7
223. J. Hagen Heterogeneous catalysis: fundamentals 2nd Ed. 1999 Industrial Catalysis: A Practical Approach 99 222
224. 2 catalyst Appl Catal A Gen 239 2003 43 58
225. J.M. Montero, D.R. Brown, P.L. Gai, A.F. Lee, and K. Wilson In situ studies of structure-reactivity relations in biodiesel synthesis over nanocrystalline MgO Chem Eng J. 161 2010 332 339
226. 2 catalyst system for soybean transesterification World Acad Sci Eng Technol 64 2012 889 893
227. 3-supported CoMo hydrodesulfurization catalysts Appl Catal A Gen 292 2005 287 294
228. 2 catalysts Catal Today 123 2007 94 103
229. 2 dry reforming Kor. J Chem Eng 31 2014 224 229
230. 2 reforming of methane J Nat Gas Chem 17 2008 179 183
231. 3 aerogel catalysts in a fluidized bed reactor Powder Technol 182 2008 474 479
232. A.S.A. Al-Fatesh, and A.H. Fakeeha Effects of calcination and activation temperature on dry reforming catalysts J Saudi Chem Soc 16 2012 55 61
233. 2 reforming of methane to syngas Appl Catal A Gen 244 2003 181 195
234. 3 catalyst Appl Catal A Gen 395 2011 114 119
235. 4 dry reforming on alumina-supported nickel catalyst Bull-Kor Chem Soc 23 2002 1149 1153
236. J.H. Edwards, and A.M. Maitra The chemistry of methane reforming with carbon dioxide and its current and potential applications Fuel Process Technol 42 1995 269 289
237. 2 nanosized samples: a catalytic, TEM, and FTIR study of the effect of calcination temperature on the CO oxidation J Catal 202 2001 256 267
238. 2 J Nat Gas Chem 17 2008 113 119
239. R. Moliner, Y. Echegoyen, I. Suelves, M.J. Lázaro, and J.M. Palacios Ni-Mg and Ni-Cu-Mg catalysts for simultaneous production of hydrogen and carbon nanofibers: the effect of calcination temperature Int J Hydrog Energy 33 2008 1719 1728
240. 3 catalysts J Catal 205 2002 289 293
241. 2 catalyst: influence of pretreatment gas atmospheres Int J Hydrog Energy 37 2012 10135 10144
242. 3 supported gold catalysts J Catal 264 2009 145 153
243. H. Zou, S. Chen, and W. Lin Effect of pretreatment methods on the performance of Cu-Zr-Ce-O catalyst for CO selective oxidation J Nat Gas Chem 17 2008 208 211
244. A.K. Prabhu, R. Radhakrishnan, and S. Ted Oyama Supported nickel catalysts for carbon dioxide reforming of methane in plug flow and membrane reactors Appl Catal A Gen 183 1999 241 252
245. MdMVM Souza, L. Clavé, V. Dubois, C.A.C. Perez, and M. Schmal Activation of supported nickel catalysts for carbon dioxide reforming of methane Appl Catal A Gen 272 2004 133 139
246. J. Xu, L. Chen, K.F. Tan, A. Borgna, and M. Saeys Effect of boron on the stability of Ni catalysts during steam methane reforming J Catal. 261 2009 158 165
247. 2 catalyst: I. Deactivation studies J Catal 161 1996 409 422
248. 4 over Ni-alumina aerogel catalysts Appl Catal A Gen 197 2000 191 200
249. 4 Appl Catal A Gen 339 2008 121 129
250. J. Newnham, K. Mantri, M.H. Amin, J. Tardio, and S.K. Bhargava Highly stable and active Ni-mesoporous alumina catalysts for dry reforming of methane Int J Hydrog Energy 37 2012 1454 1464
251. 3 catalysts for carbon dioxide reforming of methane Appl Catal B Environ 119 2012 217 226
252. A.G. Bhavani, W.Y. Kim, J.Y. Kim, and J.S. Lee Improved activity and coke resistance by promoters of nanosized trimetallic catalysts for autothermal carbon dioxide reforming of methane Appl Catal A Gen 450 2013 63 72
253. 2 reforming of methane over coprecipitated Ni-Al catalysts modified with lanthanum Appl Catal A Gen 274 2004 139 149
254. 4 over La-Ni based perovskite precursors Appl Catal A Gen 311 2006 164 171
255. 3 catalysts J Catal. 124 1990 324 335
256. E.R. Delsman, BJPF Laarhoven, MHJM De Croon, G.J. Kramer, and J.C. Schouten Comparison between conventional fixed-bed and microreactor technology for a portable hydrogen production case Chem Eng Res Des 83 2005 1063 1075
257. T. Wurzel, and L. Mleczko Engineering model of catalytic partial oxidation of methane to synthesis gas in a fluidized-bed reactor Chem Eng J 69 1998 127 133
258. 3 in fluidized- and fixed-bed reactors Catal Today 77 2002 181 189
259. F.R. García-García, M.A. Soria, C. Mateos-Pedrero, A. Guerrero-Ruiz, I. Rodríguez-Ramos, and K. Li Dry reforming of methane using Pd-based membrane reactors fabricated from different substrates J Memb Sci 435 2013 218 225
260. 3 catalysts for methane reforming with carbon dioxide J Mol Catal A Chem 235 2005 302 310
261. 3 particle mixtures in a transverse rotating magnetic field Powder Technol 107 2000 66 78
262. C. Zhu, Q. Yu, R.N. Dave, and R. Pfeffer Gas fluidization characteristics of nanoparticle agglomerates AIChE J 51 2005 426 439
263. Q. Yu, R.N. Dave, C. Zhu, J.A. Quevedo, and R. Pfeffer Enhanced fluidization of nanoparticles in an oscillating magnetic field AIChE J 51 2005 1971 1979
264. X. Zhang, CS-M Lee, D.M.P. Mingos, and D.O. Hayward Carbon dioxide reforming of methane with Pt catalysts using microwave dielectric heating Catal Lett 88 2003 129 139
265. N. Muradov, and F. Smith Catalytic activity of carbons for methane decomposition reaction Catal Today 102 2005 225 233
266. J. Menéndez, A. Arenillas, B. Fidalgo, Y. Fernández, L. Zubizarreta, and E. Calvo Microwave heating processes involving carbon materials Fuel Process Technol 91 2010 1 8
267. 4 Fuel 89 2010 4002 4007
268. J. Armor Catalysis with permselective inorganic membranes Appl Catal 49 1989 1 25
269. F. Garcia-Garcia, Y.H. Ma, I. Rodriguez-Ramos, and A. Guerrero-Ruiz High purity hydrogen production by low temperature catalytic ammonia decomposition in a multifunctional membrane reactor Catal Commun 9 2008 482 486
270. D. Mendes, V. Chibante, J.-M. Zheng, S. Tosti, F. Borgognoni, and A. Mendes Enhancing the production of hydrogen via water-gas shift reaction using Pd-based membrane reactors Int J Hydrog Energy 35 2010 12596 12608
271. P. Ferreira-Aparicio, I. RodrIÍguez-Ramos, and A. Guerrero-Ruiz On the applicability of membrane technology to the catalysed dry reforming of methane Appl Catal A Gen 237 2002 239 252
272. M.-S. Fan, A.Z. Abdullah, and S. Bhatia Catalytic technology for carbon dioxide reforming of methane to synthesis gas ChemCatChem 1 2009 192 208
273. B. Potic, S. Kersten, M. Ye, M. Van der Hoef, J. Kuipers, and W. Van Swaaij Fluidization with hot compressed water in micro-reactors Chem Eng Sci 60 2005 5982 5990
274. G. Kolb, and V. Hessel Micro-structured reactors for gas phase reactions Chem Eng J 98 2004 1 38
275. S.P. Maharrey, and D.R. Miller Quartz capillary microreactor for studies of oxidation in supercritical water AIChE J 47 2001 1203 1211
276. O. Wörz, K.P. Jäckel, T. Richter, and A. Wolf Microreactors a new efficient tool for optimum reactor design Chem Eng Sci 56 2001 1029 1033
277. 2 catalyst Fuel 102 2012 239 246
278. K. Al-Ali, S. Kodama, and H. Sekiguchi Modeling and simulation of methane dry reforming in direct-contact bubble reactor Sol Energy 102 2014 45 55
279. 4 Fuel Process Technol 92 2011 1531 1536
280. J.K. Dahl, A.W. Weimer, A. Lewandowski, C. Bingham, F. Bruetsch, and A. Steinfeld Dry reforming of methane using a solar-thermal aerosol flow reactor Ind Eng Chem Res 43 2004 5489 5495
281. 4 Nano Energy 1 2012 674 686
282. 4 using ZnO coated mesh: effect of operational parameters and optimization Sol Energy Mater Sol Cells 111 2013 31 40
283. K. Tomishige, Y. Matsuo, Y. Yoshinaga, Y. Sekine, M. Asadullah, and K. Fujimoto Comparative study between fluidized bed and fixed bed reactors in methane reforming combined with methane combustion for the internal heat supply under pressurized condition Appl Catal A Gen 223 2002 225 238
284. G. Ni, Y. Lan, C. Cheng, Y. Meng, and X. Wang Reforming of methane and carbon dioxide by DC water plasma at atmospheric pressure Int J Hydrog Energy 36 2011 12869 12876
285. T. Jiang, Y. Li, C.-j. Liu, G.-h. Xu, B. Eliasson, and B. Xue Plasma methane conversion using dielectric-barrier discharges with zeolite A Catal Today 72 2002 229 235
286. 4 by binode thermal plasma Int J Hydrog Energy 34 2009 9373 9378
287. M.-w. Li, G.-h. Xu, Y.-l. Tian, L. Chen, and H.-f. Fu Carbon dioxide reforming of methane using DC corona discharge plasma reaction J Phys Chem A 108 2004 1687 1693
288. 4 by combination of thermal plasma and catalyst Int J Hydrog Energy 33 2008 1262 1265
289. 4) by plasma jet Nat Gas Ind 27 2007 129
290. 2 using a pulsed microwave plasma under atmospheric pressure Acta Chim Sin 60 2002 1973 1980
291. A. Indarto, J.-W. Choi, H. Lee, and H.K. Song Effect of additive gases on methane conversion using gliding arc discharge Energy 31 2006 2986 2995
292. K. Hou, M. Fowles, and R. Hughes Potential catalyst deactivation due to hydrogen removal in a membrane reactor used for methane steam reforming Chem Eng Sci 54 1999 3783 3791
293. F. Gallucci, M. Van Sintannaland, and J. Kuipers Theoretical comparison of packed bed and fluidized bed membrane reactors for methane reforming Int J Hydrog Energy 35 2010 7142 7150
294. M. Dresselhaus, and I. Thomas Alternative energy technologies Nature 414 2001 332 337
295. A. Steinfeld Solar thermochemical production of hydrogen - a review Sol Energy 78 2005 603 615
296. T. Kodama High-temperature solar chemistry for converting solar heat to chemical fuels Prog Energy Combust Sci 29 2003 567 597
297. C. Agrafiotis, H. von Storch, M. Roeb, and C. Sattler Solar thermal reforming of methane feedstocks for hydrogen and syngas production - a review Renew Sustain Energy Rev 29 2014 656 682
298. R.M. Dell, and D.A. Rand Energy storage - a key technology for global energy sustainability J Power Sources 100 2001 2 17
299. K.M. Powell, and T.F. Edgar Modeling and control of a solar thermal power plant with thermal energy storage Chem Eng Sci 71 2012 138 145
300. 2 reforming of methane in a molten carbonate salt bath for use in solar thermochemical processes Energy Fuels 15 2001 60 65
301. K. Al-Ali, S. Kodama, H. Kaneko, H. Sekiguchi, Y. Tamaura, and M. Chiesa Solar upgrade of methane using dry reforming in direct contact bubble reactor In: Proceedings of 2012 SolarPACES, concentrating solar power and chemical energy systems conference Marrakech, Morocco, September 11th-14th 2012
302. X. Zhang, C.M. Lee, D.M. Mingos, and D. Hayward Carbon dioxide reforming of methane with Pt catalysts using microwave dielectric heating Catal Letters 88 2003 129 139
303. A. Babaritskii, E. Gerasimov, S. Demkin, V. Zhivotov, A. Knizhnik, and B. Potapkin The repetitive microwave discharge as a catalyst for a chemical reaction Tech Phys 45 2000 1411 1416
304. T.-S. Kim, S. Song, K.-M. Chun, and S.H. Lee An experimental study of syn-gas production via microwave plasma reforming of methane, iso-octane and gasoline Energy 35 2010 2734 2743
305. Z. Bo, J. Yan, X. Li, Y. Chi, and K. Cen Plasma assisted dry methane reforming using gliding arc gas discharge: Effect of feed gases proportion Int J Hydrog Energy 33 2008 5545 5553
306. L. Bromberg, D. Cohn, A. Rabinovich, C. O'Brie, and S. Hochgreb Plasma reforming of methane Energy Fuels 12 1998 11 18
307. 2 gas by high-energy type plasma Vacuum 65 2002 475 479
308. 3 catalyst Catal Today 89 2004 27 33
309. Y.-p. Zhang, Y. Li, Y. Wang, C.-j. Liu, and B. Eliasson Plasma methane conversion in the presence of carbon dioxide using dielectric-barrier discharges Fuel Process Technol 83 2003 101 109
310. Y. Yang Methane conversion and reforming by nonthermal plasma on pins Industrial Eng Chem Res 41 2002 5918 5926
311. G.-B. Zhao, S. John, J.-J. Zhang, L. Wang, S. Muknahallipatna, and J.C. Hamann Methane conversion in pulsed corona discharge reactors Chem Eng J 125 2006 67 79
312. J.-L. Shie, F.-J. Tsou, K.-L. Lin, and C.-Y. Chang Bioenergy and products from thermal pyrolysis of rice straw using plasma torch Bioresour Technol 101 2010 761 768
313. J.-L. Shie, F.-J. Tsou, and K.-L. Lin Steam plasmatron gasification of distillers grains residue from ethanol production Bioresour Technol 101 2010 5571 5577