Hydrogen Generation, Storage and Utilization

Hydrogen Generation, Storage and Utilization

Volumn 9781118140635, Issue , 2014, Pages 1-195

  Zhang, Jin Zhong ^a   Li, Jinghong ^b   Li, Yat ^a   Zhao, Yiping ^c  

^a UNIVERSITY OF CALIFORNIA   (United States)

^b TSINGHUA UNIVERSITY   (China)

^c UNIVERSITY OF GEORGIA   (United States)

Author keywords

[No Author keywords available]

Indexed keywords

FOSSIL FUELS; HYDRIDES; HYDROGEN STORAGE; METALLURGY; SOLAR POWER GENERATION;

HIGH PRESSURE COMPRESSION; HYDROGEN EXTRACTION; HYDROGEN GENERATIONS; HYDROGEN UTILIZATION; INNOVATIVE METHOD; PHOTOELECTROCHEMICALS; SCIENTIFIC FOUNDATIONS; STORAGE OF HYDROGEN;

HYDROGEN PRODUCTION;

EID: 84923845076     PISSN: None     EISSN: None     Source Type: Book    
DOI: 10.1002/9781118875193     Document Type: Book

References (393)

1. Irwin, J.A. Astrophysics: Decoding the Cosmos, John Wiley & Sons, Chichester, 2007.
2. + states of the hydrogen molecule. Journal of Molecular Spectroscopy 1990, 143(2), 212-230.
3. + states of the hydrogen molecule. Journal of Molecular Spectroscopy 1990, 143(2), 237-250.
4. Flemming, E., Wilhelmi, O., Schmoranzer, H., Glassmaujean, M. Coherence effects in the polarization of Lyman-Alpha fluorescence following photodissociation of H2 and D2. Journal of Chemical Physics 1995, 103(10), 4090-4096.
5. Clark, A.P., Brouard, M., Quadrini, F., Vallance, C. Atomic polarization in the photodissociation of diatomic molecules. Physical Chemistry Chemical Physics 2006, 8(48), 5591-5610.
6. Ogden, J. Review of Small Stationary Reformers for Hydrogen Production, The International Energy Agency, Paris, 2001.
7. Beaver, M.G., Caram, H.S., Sircar, S. Sorption enhanced reaction process for direct production of fuel-cell grade hydrogen by low temperature catalytic steam-methane reforming. Journal of Power Sources 2010, 195(7), 1998-2002.
8. Geissler, K., Newson, E., Vogel, F., Truong, T.B., Hottinger, P., Wokaun, A. Autothermal methanol reforming for hydrogen production in fuel cell applications. Physical Chemistry Chemical Physics 2001, 3(3), 289-293.
9. Papavasiliou, J., Avgouropoulos, G., Ioannides, T. In situ combustion synthesis of structured Cu-Ce-O and Cu-Mn-O catalysts for the production and purification of hydrogen. Applied Catalysis B-Environmental 2006, 66(3-4), 168-174.
10. Lindstrom, B., Agrell, J., Pettersson, L.J. Combined methanol reforming for hydrogen generation over monolithic catalysts. Chemical Engineering Journal 2003, 93(1), 91-101.
11. Pattekar, A.V., Kothare, M.V. A microreactor for hydrogen production in micro fuel cell applications. Journal of Microelectromechanical Systems 2004, 13(1), 7-18.
12. Haryanto, A., Fernando, S., Murali, N.; Adhikari, S. Current status of hydrogen production techniques by steam reforming of ethanol: A review. Energy & Fuels 2005, 19(5), 2098-2106.
13. Fatsikostas, A.N., Kondarides, D.I., Verykios, X.E. Steam reforming of biomass-derived ethanol for the production of hydrogen for fuel cell applications. Chemical Communications 2001, (9), 851-852.
14. Fierro, V., Klouz, V., Akdim, O., Mirodatos, C. Oxidative reforming of biomass derived ethanol for hydrogen production in fuel cell applications. Catalysis Today 2002, 75(1-4), 141-144.
15. Wang, B.W., Lu, Y.J., Zhang, X., Hu, S.H. Hydrogen generation from steam reforming of ethanol in dielectric barrier discharge. Journal of Natural Gas Chemistry 2011, 20(2), 151-154.
16. Vaidya, P.D., Rodrigues, A.E. Glycerol reforming for hydrogen production: A review. Chemical Engineering & Technology 2009, 32(10), 1463-1469.
17. Dauenhauer, P. J., Salge, J. R. Schmidt, L. D., Renewable hydrogen by autothermal steam reforming of volatile carbohydrates. Journal of Catalysis 2006, 244(2), 238-247.
18. Sutton, D., Kelleher, B., Ross, J.R.H. Review of literature on catalysts for biomass gasification. Fuel Processing Technology 2001, 73(3), 155-173.
19. Adhikari, S., Fernando, S., Haryanto, A. Production of hydrogen by steam reforming of glycerin over alumina-supported metal catalysts. Catalysis Today 2007, 129(3-4), 355-364.
20. Hacker, V., Kordesch, K. Ammonia crackers. In W. Vielstich, A. Lamm, and H.A. Gasteiger, eds., Handbook of Fuel Cells: Fundamentals, Technology and Applications, John Wiley & Sons, Chichester, 2003, Vol. 3, pp. 121-127.
21. Appl, M. Ammonia, Principles and Industrial Practice. New York, Wiley-VCH, 1999.
22. Amin, A.M., Croiset, E.M., Epling, W. Review of methane catalytic cracking for hydrogen production. International Journal of Hydrogen Energy 2011, 36(4), 2904-2935.
23. Avdeeva, L.B., Reshetenko, T.V., Ismagilov, Z.R., Likholobov, V.A. Iron-containing catalysts of methane decomposition: Accumulation of filamentous carbon. Applied Catalysis a-General 2002, 228(1-2), 53-63.
24. 2. Metallurgical Transactions 1970, 1(10), 2972-2975.
25. 2 on a silica-supported nickel-catalyst. Journal of Catalysis 1992, 135(1), 147-155.
26. Wang, K., Li, W.S., Zhou, X.P. Hydrogen generation by direct decomposition of hydrocarbons over molten magnesium. Journal of Molecular Catalysis A: Chemical 2008, 283(1-2), 153-157.
27. Mazloomi, K., Sulaiman, N.B., Moayedi, H. Electrical efficiency of electrolytic hydrogen production. International Journal of Electrochemical Science 2012, 7, 3314-3326.
28. Djafour, A., Matoug, M., Bouras, H., Bouchekima, B., Aida, M.S., Azoui, B. Photovoltaic-assisted alkaline water electrolysis: Basic principles. International Journal of Hydrogen Energy 2011, 36, 4117-4124.
29. Tachibana, Y., Vayssieres, L., Durrant, J. R. Artificial photosynthesis for solar water-splitting. Nature Photonics 2012, 6, 511-518.
30. Wang, G.M., Ling, Y.C., Li, Y. Oxygen-deficient metal oxide nanostructures for photoelectrochemical water oxidation and other applications. Nanoscale, 2012, 4, 6682-6691.
31. Kudo, A., Miseki, Y. Heterogeneous photocatalyst materials for water splitting. Chemical Society Reviews 2009, 38(1), 253-278.
32. Fujishima, A., Honda, K. Electrochemical photolysis of water at a semiconductor electrode. Nature 1972, 238, 37-38.
33. Li, Y., Zhang, J.Z. Hydrogen generation from photoelectrochemical water splitting based on nanomaterials. Laser & Photonics Reviews 2010, 4, 517-528.
34. 2 nanowires. Nano Letters 2012, 12, 26-32.
35. 2 generation using colloidal nanorod heterostructures. Journal of the American Chemical Society 2012, 134, 11701-11708.
36. 2 core/shell nanowire arrays with enhanced photoactivity. Nano Letters 2009, 9, 410-415.
37. 2 nanowire arrays for photoelectrochemical water splitting. Nano Letters 2011, 11, 3026-3033.
38. Wang, G.M., Yang, X.Y., Qian, F., Zhang, J.Z., Li, Y. Double-sided CdS and CdSe quantum dot co-sensitized ZnO nanowire arrays for photoelectrochemical hydrogen generation. Nano Letters 2010, 10, 1088-1092.
39. Yang, X.Y., Wolcott, A., Wang, G.M., Sobo, A., Fitzmorris, R.C., Qian, F., Zhang, J.Z., Li, Y. Nitrogen-doped ZnO nanowire arrays for photoelectrochemical water splitting. Nano Letters 2009, 9, (6), 2331-2336.
40. 3 heterostructure nanotube arrays for improved photoelectrochemical performance. ACS Nano 2010, 4, 387-395.
41. Banerjee, S., Mohapatra, S.K., Misra, M. Synthesis of TaON nanotube arrays by sonoelectrochemical anodization followed by nitridation: A novel catalyst for photoelectrochemical hydrogen generation from water. Chemical Communications 2009, 46, 7137-7139.
42. Ito, S., Thampi, K.R., Comte, P., Liska, P., Gratzel, M. Highly active meso-microporous TaON photocatalyst driven by visible light. Chemical Communications 2009, 2, 268-270.
43. 5 photocatalysts by modification with alkaline metal salts. Journal of the American Chemical Society 2012, 134, 19993-19996.
44. Sun, J.W., Liu, C., Yang, P.D. Surfactant-free, large-scale, solution-liquid-solid growth of gallium phosphide nanowires and their use for visible-light-driven hydrogen production from water reduction. Journal of the American Chemical Society 2011, 133, 19306-19309.
45. Zhang, R.Q., Liu, X.M., Wen, Z., Jiang, Q. Prediction of silicon nanowires as photocatalysts for water splitting: band structures calculated using density functional theory. Journal of Physical Chemistry C 2011, 115, 3425-3428.
46. Wang, F.Y., Yang, Q.D., Xu, G., Lei, N.Y., Tsang, Y.K., Wong, N.B., Ho, J.C. Highly active and enhanced photocatalytic silicon nanowire arrays. Nanoscale 2011, 3, 3269-3276.
47. Hoang, S., Berglund, S.P., Hahn, N.T., Bard, A.J., Mullins, C.B. Enhancing visible light photo-oxidation of water with TiO2 nanowire arrays via cotreatment with H2 and NH3: synergistic effects between Ti3+ and N. Journal of the American Chemical Society 2012, 134, 3659-3662.
48. Chen, X., Liu, L., Yu, P.Y., Mao, S.S. Increasing solar absorption for photocatalysis with black hydrogenated titanium dioxide nanocrystals. Science 2011, 331, 746-750.
49. Thompson, T.L., Yates, J.T. Surface science studies of the photoactivation of TiO2-new photochemical processes. Chemical Reviews 2006, 106, 4428-4453.
50. Lu, X.H., Wang, G.M., Xie, S.L., Shi, J.Y., Li, W., Tong, Y.X., Li, Y. Efficient photocatalytic hydrogen evolution over hydrogenated ZnO nanorod arrays. Chemical Communications 2012, 48, 7717-7719.
51. Wang, G.M., Ling, Y.C., Wang, H.Y., Yang, X.Y., Wang, C.C., Zhang, J.Z., Li, Y. Hydrogen-treated WO3 nanoflakes show enhanced photostability. Energy & Environmental Science 2012, 5, 6180-6187.
52. Tabata, M., Maeda, K., Higashi, M., Lu, D.L., Takata, T., Abe, R., Domen, K. Modified Ta3N5 powder as a photocatalyst for O-2 Evolution in a two-step water splitting system with an iodate/iodide shuttle redox mediator under visible light. Langmuir 2010, 26, 9161-9165.
53. Fang, C. M., Orhan, E., de Wijs, G.A., Hintzen, H.T., de Groot, R.A., Marchand, R., Saillard, J.Y., de With, G. The electronic structure of tantalum (oxy)nitrides TaON and Ta3N5. Journal of Materials Chemistry 2011, 11, 1248-1252.
54. Hitoki, G., Takata, T., Kondo, J.N., Hara, M., Kobayashi, H., Domen, K. An oxynitride, TaON, as an efficient water oxidation photocatalyst under visible light irradiation (lambda {long leftwards double arrow} 500 nm). Chemical Communications 2002, 16, 1698-1699.
55. Han, Z.J., Qiu, F., Eisenberg, R., Holland, P.L., Krauss, T.D. Robust photogeneration of H2 in water using semicondutor nanocrystals and a nickel catalyst. Science 2012, 338, 1321-1324.
56. Li, Q., Guo, B.D., Yu, J. G., Ran, J.R., Zhang, B.H., Yan, H.J., Gong, J.R. Highly efficient visible-light-driven photocatalytic hydrogen production of CdS-cluster-decorated graphene nanosheets. Journal of The American Chemical Society 2011, 133, 10878-10884.
57. Liu, C., Dasgupta, N.P., Yang, P.D. Semiconductor nanowires for artificial photosynthesis. Chemistry of Materials 2013, in press (DOI: 10.1021/cm4023198).
58. Paracchino, A., Laporte, V., Sivula, K., Gratzel, M., Thimsen, E. Highly active oxide photocathode for photoelectrochemical water reduction. Nature Materials 2010, 10, 456-461.
59. Bookbinder, D.C., Lewis, N.S., Bradley, M.G., Bocarsly, A.B., Wrighton, M.S. Photoelectrochemical reduction of N, N-dimethyl-4,4-Bipyridinium in aqueous media at p type silicon-sustained photogeneration of a species capable of evolving hydrogen. Journal of The American Chemical Society 1979, 101, 7721-7723.
60. Bookbinder, D.C., Bruce, J.A., Dominey, R.N., Lewis, N.S., Wrighton, M.S. Synthesis and characterization of a photosensitive interface for hydrogen generation-chemically modified p-type semiconducting silicon photocathode. Proceedings of the National Academy of Sciences of the United States of America-Physical Sciences 1980, 77, 6280-6284.
61. Boettcher, S.W., Spurgeon, J.M., Putnam, M.C., Warren, E.L., Turner-Evans, D.B., Kelzenberg, M.D., Maiolo, J.R., Atwater, H.A., Lewis, N.S. Energy-conversion properties of vapor-liquid-solid-grown silicon wire-array photocathodes. Science 2010, 327, 185-187.
62. Oh, I., Kye, J., Hwang, S. Enhanced photoelectrochemical hydrogen production from silicon nanowire array photocathode. Nano Letters 2012, 12, 298-302.
63. Liu, C., Sun, J.W., Tang, J.Y., Yang, P.D. Zn-doped p-type gallium phosphide nanowire photocathodes from a surfactant-free solution synthesis. Nano Letters 2012, 12, 5407-5411.
64. 2 in aqueous electrolytes toward photoelectrochemical water splitting. Journal of the Electrochemical Society 1998, 145, 3335-3339.
65. Lee, M.H., Takei, K., Zhang, J.J., Kapadia, R., Zheng, M., Chen, Y.Z., Nah, J., Matthews, T. S., Chueh, Y.L., Ager, J.W., Javey, A. p-Type InP nanopillar photocathodes for efficient solar-driven hydrogen production. Angewandte Chemie-International Edition 2012, 51, 10760-10764.
66. Pijpers, J.J.H., Winkler, M.T., Surendranath, Y., Buonassisi, T., Nocera, D.G. Light-induced water oxidation at silicon electrodes functionalized with a cobalt oxygen-evolving catalyst. Proceedings of the National Academy of Sciences of the United States of America 2012, 108, 10056-10061.
67. 3-based films for water oxidation. Nano Letters 2011, 11, 3503-3509.
68. Wheeler, D.A., Wang, G.M., Ling, Y.C., Li, Y., Zhang, J.Z. Nanostructured hematite: synthesis, characterization, charge carrier dynamics, and photoelectrochemical properties. Energy & Environmental Science 2012, 5, 6682-6702.
69. 2 nanotube arrays with high aspect ratios for efficient solar water splitting. Nano Letters 2006, 6, 24-28.
70. Cesar, I., Sivula, K., Kay, A. Zboril, R., Grätzel, M. Influence of feature size, film thickness, and silicon doping on the performance of nanostructured hematite photoanodes for solar water splitting. Journal of Physical Chemistry C 2009, 113, 772-782.
71. Ling, Y.C., Wang, G.M., Wheeler, D.A., Zhang, J.Z., Li, Y. Sn-doped hematite nanostructures for photoelectrochemical water splitting. Nano Letters 2011, 11, 2119-2125.
72. Ling, Y., Wang, G., Reddy, J., Wang, C., Zhang, J., Li, Y. Influence of oxygen content on thermal activation of hematite nanowires. Angewandte Chemie International Edition 2012, 51, 4074-4079.
73. 4 photoelectrodes for solar water oxidation. Energy & Environmental Science 2011, 4, 5028-5034.
74. 3 electrodes for enhanced photoactivity of water oxidation. Energy & Environmental Science 2011, 4, 1781-1787.
75. Demirbas, A. Biohydrogen: For Future Engine Fuel Demands, Trabzon, Springer, 2009.
76. Larsen H., Feidenhans'l R., Petersen LS. Hydrogen and its competitors, Risø energy Report 3, Risø National Laboratory, Roskilde, Denmark, November 2004.
77. Milne TA., Elam CC., Evans RJ. Hydrogen from biomass: State of the art and research challenges, Report for IEA, IEA/H2/TR-02/001. National Renewable Energy Laboratory, Golden, CO, 2002.
78. Patel AG., Maheshwari NK., Vijayan PK., Sinha RK. A study on sulfur-iodine (S-I) thermochemical water splitting process for hydrogen production from nuclear heat. In Proceedings of the Sixteenth Annual Conference of Indian Nuclear Society, Science behind Nuclear Technology, Mumbai, India, November 15-18, 2005.
79. Demirbas A. Yields of hydrogen of gaseous products via pyrolysis from selected biomass samples. Fuel 2001, 80, 1885-1891.
80. Wang D., Czernik S., Montane D., Mann M., Chornet E. Biomass to hydrogen via fast pyrolysis and catalytic steam reforming of the pyrolysis oil or its fractions. Industrial & Engineering Chemistry Research 1997, 36, 1507-1518.
81. Yan Q., Guo L., Lu Y. Thermodynamic analysis of hydrogen production from biomass gasification in supercritical water. Energy Conversion and Management 2006, 47, 1515-1528.
82. Swami SM., Chaudhari V., Kim DS., Sim SJ., Abraham MA. Production of hydrogen from glucose as a biomass simulant: Integrated biological and thermochemical approach. Industrial & Engineering Chemistry Research 2008, 47, 3645-3651.
83. Sricharoenchaikul V., Marukatat C., Atong T. Fuel production from physic nut (Jatropha Curcas L.) waste by fixed-bed pyrolysis process. In Proceedings of the 3rd Conference on Energy Network of Thailand, ENETT2550-072, Bangkok, Thailand, May 23-25, 2007.
84. Das D., Veziroglu TN. Hydrogen production by biological processes: A survey of literature. International Journal of Hydrogen Energy 2001, 26, 13-28.
85. Nandi R., Sengupta S. Microbial production of hydrogen: An overview. Critical Reviews in Microbiology 1998, 24, 61-84.
86. Cheong DY., Hansen CL. Bacterial stress enrichment enhances anaerobic hydrogen production in cattle manure sludge. Applied Microbiology and Biotechnology 2006, 72, 635-643.
87. Ren N., Li J., Li B., Wang Y., Liu S. Biohydrogen production from molasses by anaerobic fermentation with a pilotscale bioreactor system. International Journal of Hydrogen Energy 2006, 31, 2147e57.
88. O-Thong S., Prasertsan P., Karakashev D., Angelidaki I. Thermophilic fermentative hydrogen production by the newly isolated Thermoanaerobacterium thermosaccharolyticum PSU-2. International Journal of Hydrogen Energy 2008, 33, 1204-1214.
89. Devrije T., Bakker RR., Budde MAW., Lai MH., Mars AE., Claassen PAM. Efficient hydrogen production from the lignocellulosic energy crop Miscanthus by the extreme thermophilic bacteria Caldicellulosiruptor saccharolyticus and Thermotoga neapolitana. Biotechnology Biofuels 2009, 2, 12.
90. Zheng H., O'Sullivan C., Mereddy R., Zeng RJ., Duke M., Clarke W. Production of bio-hydrogen using a membrane anaerobic reactor: Limitations due to diffusion. In Proceedings of the Environmental Research Event 2009, Noosa Heads, Queensland, Australia, May 10-13, 2009.
91. Kotay SM., Das D. Biohydrogen as a renewable energy resourced prospects and potentials. International Journal of Hydrogen Energy 2008, 33, 258-263.
92. Tao Y., Chen Y., Wu Y., He Y., Zhou Z. High hydrogen yield from a two-step process of dark-and photo-fermentation of sucrose. International Journal of Hydrogen Energy 2007, 32, 200-206.
93. Demirbas A. Thermochemical conversion of mosses and algae to gaseous products. Energy Sources. Part A. Recovery, Utilization, and Environmental Effects 2009, 31, 746-753.
94. Balat H. Prospects of biofuels for a sustainable energy future: A critical assessment. Energy Education Science and Technology, Part A 2010, 24, 85-111.
95. Encinar JM., Beltran FJ., Ramiro A., Gonzalez JF. Pyrolysis/gasification of agricultural residues by carbon dioxide in the presence of different additives: Influence of variables. Fuel Processing Technology 1998, 55, 219-233.
96. Balat M. New biofuel production technologies. Energy Education Science and Technology, Part A 2009, 22, 147-161.
97. Ni M., Leung DYC., Leung MKH., Sumathy K. An overview of hydrogen production from biomass. Fuel Processing Technology 2006, 87, 461-472.
98. Demirbas A. Partial hydrogenation effect of moisture contents on the combustion oils from biomass pyrolysis. Energy Sources. Part A. Recovery, Utilization, and Environmental Effects 2008, 30, 508-515.
99. Demirbas A. Hydrogen-rich gases from biomass via pyrolysis and air-steam gasification. Energy Sources. Part A. Recovery, Utilization, and Environmental Effects 2009, 31, 1728-1736.
100. Demirbas A. Gaseous products from biomass by pyrolysis and gasification: Effects of catalyst on hydrogen yield. Conversion and Management 2002, 43, 897-909.
101. Demirbas A. Hydrogen production via pyrolytic degradation of agricultural residues. Energy Sources. Part A. Recovery, Utilization, and Environmental Effects 2005, 27, 769-775.
102. Berman A., Karn RK., Epstein M. Kinetics of steam reforming of methane on Ru/Al2O3 catalyst promoted with Mn oxides. Applied Catalysis A: General 2005, 282, 73-83.
103. Galdamez JM., Garcia L., Bilbao R. Hydrogen production by steam reforming of bio-oil using coprecipitated Ni-Al catalysts. Acetic acid as a model compound. Energy Fuels 2005, 19, 1133-1142.
104. Vagia EC., Lemonidou AA. Thermodynamic analysis of hydrogen production via steam reforming of selected components of aqueous bio-oil fraction. International Journal of Hydrogen Energy 2007, 32, 212-223.
105. Wu C., Yan Y., Li T., Qi W. Preparation of hydrogen through catalytic steam reforming of bio-oil. The Chinese Journal of Process Engineering 2007, 7, 1114-1119.
106. Evans RJ., Chornet E., Czernik S., Feik C., French R., Phillips S., et al. Renewable hydrogen production by catalytic steam reforming of peanut shells pyrolysis products. American Chemical Society: Division of Fuel Chemistry 2002, 47, 757-758.
107. Nath K., Das D. Hydrogen from biomass. Current Science 2003, 85, 265-271.
108. Turner J., Sverdrup G., Mann MK., Maness PC., Kroposki B., Ghirardi M., et al. Renewable hydrogen production. International Journal of Energy Research 2008, 32, 379-407.
109. Demirbas MF. Technological options for producing hydrogen from renewable resources. Energy Sources. Part A. Recovery, Utilization, and Environmental Effects 2006, 28, 1215-1223.
110. Demirbas A. Hydrogen production from carbonaceous solid wastes by steam reforming. Energy Sources. Part A. Recovery, Utilization, and Environmental Effects 2008, 30, 924-931.
111. Yoon SJ., Choi YC., Lee JG. Hydrogen production from biomass tar by catalytic steam reforming. Energy Conversion and Management 2010, 51, 42-47.
112. Stassen HEM., Knoef HAM. Small scale gasification systems, Biomass Technology Group, University of Twente, The Netherlands, 1993.
113. Balat M. Sustainable transportation fuels from biomass materials. Energy Education Science and Technology 2006, 17, 83-103.
114. Demirbas A. Converting biomass derived synthetic gas to fuels via Fisher-Tropsch synthesis. Energy Sources. Part A. Recovery, Utilization, and Environmental Effects 2007, 29, 1507-1512.
115. Wei L., Xu S., Zhang L., Liu C., Zhu H., Liu S. Steam gasification of biomass for hydrogen-rich gas in a free-fall reactor. International Journal of Hydrogen Energy 2007, 32, 24-31.
116. Demirbas A. Thermochemical conversion of hazelnut shell to gaseous products for production of hydrogen. Energy Sources. Part A. Recovery, Utilization, and Environmental Effects 2005, 27, 339-347.
117. Kriengsak SN., Buczynski R., Gmurczyk J., Gupta AK. Hydrogen production by high-temperature steam gasification of biomass and coal. Environmental Engineering Science 2009, 26, 739-744.
118. Demirbas MF. Producing hydrogen from biomass via non-conventional processes. Energy, Exploration & Exploitation 2004, 22, 225-233.
119. Demirbas MF. Hydrogen from various biomass species via pyrolysis and steam gasification processes. Energy Source A 2006, 28, 245-252.
120. Wu W., Kawamoto K., Kuramochi H. Hydrogen-rich synthesis gas production from waste wood via gasification and reforming technology for fuel cell application. Journal of Material Cycles and Waste Management 2006, 8, 70-77.
121. Demirbas A. Hydrogen production from biomass by gasification process. Energy Sources. Part A. Recovery, Utilization, and Environmental Effects 2002, 24, 59-68.
122. Dupont C., Boissonnet G., Seiler JM., Gauthier P., Schweich D. Study about the kinetic processes of biomass steam gasification. Fuel 2007, 86, 32-40.
123. Maschio G., Lucchesi A., Stoppato G. Production of syngas from biomass. Bioresource Technology 1994, 48, 119-126.
124. Demirbas A. Pyrolysis and steam gasification processes of black liquor. Energy Conversion and Management 2002, 43, 877-884.
125. Lv P., Chang J., Wang T., Fu Y., Chen Y. Hydrogen-rich gas production from biomass catalytic gasification. Energy Fuels 2004, 18, 228-233.
126. Demirbas A., Caglar A. Catalytic steam reforming of biomass and heavy oil residues to hydrogen. Energy Education Science and Technology 1998, 1, 45-52.
127. Luo S., Xiao B., Guo X., Hu Z., Liu S., He M. Hydrogen-rich gas from catalytic steam gasification of biomass in a fixed bed reactor: Influence of particle size on gasification performance. International Journal of Hydrogen Energy 2009, 34, 1260-1264.
128. Demirbas A. Characterization of products from two lignite samples by supercritical fluid extraction. Energy Sources. Part A. Recovery, Utilization, and Environmental Effects 2004, 26, 933-939.
129. Demirbas A. Diesel-like fuel from tallow by pyrolysis and supercritical water liquefaction. Energy Sources. Part A. Recovery, Utilization, and Environmental Effects 2009, 31, 824-830.
130. Lu YJ., Guo LJ., Ji CM., Zhang XM., Hao XH., Yan QH. Hydrogen production by biomass gasification in supercritical water: A parametric study. International Journal of Hydrogen Energy 2006, 31, 822-831.
131. Guo LJ., Lu YJ., Zhang XM., Ji CM., Guan Y., Pei AX. Hydrogen production by biomass gasification in supercritical water: A systematic experimental and analytical study. Catalysis Today 2007, 129, 275-286.
132. Yan Q., Guo L., Lu Y. Thermodynamic analysis of hydrogen production from biomass gasification in supercritical water. Energy Conversion and Management 2006, 47, 1515-1528.
133. Demirbas A. Biohydrogen: For Future Engine Fuel Demands, Springer-Verlag, London, 2009.
134. Demirbas A. Biorefineries: Current activities and future developments. Energy Conversion and Management 2009, 50, 2782-2801.
135. Wang D., Czernik S., Montane D., Mann M., Chornet E. Biomass to hydrogen via fast pyrolysis and catalytic steam reforming of the pyrolysis oil or its fractions. Industrial & Engineering Chemistry Research 1997, 36, 1507-1518.
136. Das D., Veziroglu TN. Hydrogen production by biological processes: A survey of literature. International Journal of Hydrogen Energy 2001, 26, 13-28.
137. Demirbas A. Biohydrogen generation from organic waste. Energy Sources. Part A. Recovery, Utilization, and Environmental Effects 2008, 30, 475-482.
138. Li J., Li B., Zhu G., Ren N., Bo L., He J. Hydrogen production from diluted molasses by anaerobic hydrogen producing bacteria in an anaerobic baffled reactor (ABR). International Journal of Hydrogen Energy 2007, 32, 3274-3283.
139. Zhi X., Yang H., Yuan Z., Shen J. Bio-hydrogen production of anaerobic bacteria in reverse micellar media. International Journal of Hydrogen Energy 2008, 33, 4747-4754.
140. Nath K., Das D. Biohydrogen production as a potential energy resource: Present state-of-art. Journal of Scientific and Industrial Research 2004, 63, 729-738.
141. Das D., Khanna N., Veziroglu TN. Recent developments in biological hydrogen production processes. Chemical Industry and Chemical Engineering Quarterly 2008, 14, 57-67.
142. Das D., Dutta T., Nath K., Kotay SM., Das AK., Veziroglu TN. Role of Fe-hydrogenase in biological hydrogen production. Current Science 2006, 90, 1627-1637.
143. Benemann JR. Hydrogen production by microalgae. Journal of Applied Phycology 2000, 12, 291-300.
144. Melis A., Zhang L., Forestier M., Ghirardi ML., Seibert M. Sustained photobiological hydrogen gas production upon reversible inactivation of oxygen evolution in the green alga Chlamydomonas reinhardtii. Plant Physiology 2000, 122, 127-136.
145. Resnick RJ. The economics of biological methods of hydrogen production. Master thesis, Massachusetts Institute of Technology, Sloan School of Management, Management of Technology Program; 2004.
146. Manish S., Banerjee R. Comparison of biohydrogen production processes. International Journal of Hydrogen Energy 2008, 33, 279-286.
147. Hallenbeck PC., Benemann JR. Biological hydrogen production; fundamentals and limiting processes. International Journal of Hydrogen Energy 2002, 27, 1185-1193.
148. Balat M. Production of hydrogen via biological processes. Energy Sources. Part A. Recovery, Utilization, and Environmental Effects 2009, 31, 1802-1812.
149. Levin DB., Pitt L., Love M. Biohydrogen production: Prospects and limitations to practical application. International Journal of Hydrogen Energy 2004, 29, 173-185.
150. Fedorov AS., Tsygankov AA., Rao KK., Hall DO. Hydrogen photoproduction by Rhodobacter sphaeroides immobilised on polyurethane foam. Biotechnology Letters 1998, 20, 1007-1009.
151. Gadhamshetty V., Sukumaran A., Nirmalakhandan N., Myint MT. Photofermentation of malate for biohydrogen production: A modeling approach. International Journal of Hydrogen Energy 2008, 33, 2138-2146.
152. Ren N., Li J., Li B., Wang Y., Liu S. Biohydrogen production from molasses by anaerobic fermentation with a pilot-scale bioreactor system. International Journal of Hydrogen Energy 2006, 31, 2147-2157.
153. Hawkes FR., Dinsdale R., Hawkes DL., Hussy I. Sustainable fermentative hydrogen production: Challenges for process optimisation. International Journal of Hydrogen Energy 2002, 27, 1339-1347.
154. Nath K., Das D. Improvement of fermentative hydrogen production: Various approaches. Applied Microbiology and Biotechnology 2004, 65, 520-529.
155. Tao Y., Chen Y., Wu Y., He Y., Zhou Z. High hydrogen yield from a two-step process of dark-and photo-fermentation of sucrose. International Journal of Hydrogen Energy 2007, 32, 200-206.
156. Kotay SM., Das D. Biohydrogen as a renewable energy resource: Prospects and potentials. International Journal of Hydrogen Energy 2008, 33, 258-263.
157. Kapdan IK., Kargi F. Bio-hydrogen production from waste materials. Enzyme and Microbial Technology 2006, 38, 569-582.
158. Targets for onboard hydrogen storage systems for light-duty vehicles. http://www1.eere.energy.gov/hydrogenandfuelcells/storage/pdfs/targets_onboard_hydro_storage_explanation.pdf (last accessed December 9, 2013).
159. Status of hydrogen storage technologies. http://www1.eere.energy.gov/hydrogenandfuelcells/storage/tech_status.html (last accessed December 9, 2013).
160. Zhou, L., Zhou, Y.P. Determination of compressibility factor and fugacity coefficient of hydrogen in studies of adsorptive storage. International Journal of Hydrogen Energy 2001, 26(6), 597-601.
161. Wasserstoff Daten: Hydrogen data. http://www.h2data.de/(last accessed December 9, 2013).
162. Hydrogen Composite Tank Program. http://www1.eere.energy.gov/hydrogenandfuelcells/pdfs/32405b27.pdf (last accessed December 9, 2013).
163. Pathways to commercial success: Technologies and products supported by the hydrogen, Fuel Cells & Infrastructure Technologies Program. http://www1.eere.energy.gov/hydrogenandfuelcells/pdfs/pathways_success_hfcit.pdf (last accessed December 18, 2013).
164. Silbey, R.J., Alberty, R.A., Bawendi, M.G. Physical Chemistry, 4th ed., John Wiley & Sons, Hoboken, NJ, 2005.
165. Strobel, R., Oszcipok, M., Fasil, M., Rohland, B., Jorissen, L., Garche, J. The compression of hydrogen in an electrochemical cell based on a PE fuel cell design. Journal of Power Sources 2002, 105(2), 208-215.
166. Abdulla, A., Laney, K., Padilla, M., Sundaresan, S., Benziger, J. Efficiency of hydrogen recovery from reformate with a polymer electrolyte hydrogen pump. AIChE Journal 2011, 57, 1767-1779.
167. Leung, W.B., March, N.H., Motz, H. Primitive phase diagram for hydrogen. Phys. Lett. A 1976, 56, 425.
168. Barron, R.F. Cryogenic Systems, 2nd ed., Oxford University Press, New York, 1985.
169. Flynn, T.M. Cryogenic Engineering, Dekker, New York, 1997.
170. Züttel, A., Remhof, A., Borgschulte, A., Friedrichs, O. Hydrogen: The future energy carrier. Philosophical Transactions of the Royal Society A 2010, 368, 3329-3342.
171. Schlapbach, L., Anderson, I., Burger, J.P. Hydrogen in metals. In K.H.J Buschow, ed., Electronic and Magnetic Properties of Metals and Ceramics Part II, VCH, Weinheim, 1994, Vol. 3B, p .271.
172. Zuttel, A. Materials for hydrogen srorage. Materials Today 2003, 6, 24-33.
173. Schlapbach, L., Zuttel, A. Hydrogen-storage materials for mobile applications. Nature 2001, 414(6861), 353-358.
174. Mintz, M.H., Zeiri, Y. Hydriding kinetics of powders. Journal of Alloys and Compounds 1994, 216(2), 159-175.
175. Avrami, M. Kinetics of phase change. I. General theory. Journal of Chemical Physics 1939, 7, 1103-1112.
176. http://www1.eere.energy.gov/hydrogenandfuelcells/storage/pdfs/targets_onboard_hydro_storage_explanation.pdf (last accessed December 19, 2013).
177. Broom, D.P. Hydrogen Storage Materials: The Characterisation of Their Storage Properties, Springer, London, 2011.
178. Hirscher, M. Handbook of Hydrogen Storage: New Materials for Future Energy Storage, WILEY-VCH, Weinheim, 2010.
179. Züttel, A., Borgschulte, A., Schlapbach, L. Hydrogen as a Future Energy Carrier, Wiley-VCH, Weinheim, 2008.
180. Stampfer, J.F.J., Holley, C.E.J., Suttle, J.F. The magnesium-hydrogen system. Journal of the American Chemical Society 1960, 82, 3504-350.
181. Dornheim, M., Eigen, N., Barkhordarian, G., Klassen, T., Bormann, R. Tailoring hydrogen storage materials towards application. Advanced Engineering Materials 2006, 8(5), 377-385.
182. Ross, D.K. Hydrogen storage: The major technological barrier to the development. of hydrogen fuel cell cars. Vacuum 2006, 80(10), 1084-1089.
183. Huot, J., Liang, G., Schulz, R., Mechanically alloyed metal hydride systems. Applied Physics A 2001, 72, 187-195.
184. Barkhordarian, G., Klassen, T., Bormann, R., Kinetic investigation of the effect of milling time on the hydrogen sorption reaction of magnesium catalyzed with different Nb2O5 contents. Journal of Alloys and Compounds 2006, 407, 249-255.
185. Sorensen, B. Hydrogen and Fuel Cells, Elsevier Academic Press, Amsterdam, 2005.
186. Sandrock, G. A panoramic overview of hydrogen storage alloys from a gas reaction point of view. Journal of Alloys and Compounds 1999, 293-295, 877-888.
187. Sorensen, B., Hydrogen and Fuel Cells, 3rd ed., Elsevier Academic Press, Amsterdam, 2004.
188. Bogdanovic, B., Schwickardi, M. Ti-doped alkali metal aluminium hydrides as potential novel reversible hydrogen storage materials. Journal of Alloys and Compounds 1997, 253-254, 1-9.
189. Chen, P., Xiong, Z., Luo, J.Z., Lin, J., Tan, K.L. Interaction of hydrogen with metal nitrides and imides. Nature 2002, 420, 302-304.
190. Jensen, C.M., Gross, K.J. Development of catalytically enhanced sodium aluminium hydride as a hydrogen-storage material. Applied Physics A 2001, 72, 213-219.
191. Berube, V., Radtke, G., Dresselhaus, M., Chen, G. Size effects on the hydrogen storage properties of nanostructured metal hydrides: A review. International Journal of Energy Research 2007, 31(6-7), 637-663.
192. Zaluski, L., Zaluska, A., Tessier, P., StromOlsen, J.O., Schulz, R. Nanocrystalline hydrogen absorbing alloys. In Metastable, Mechanically Alloyed and Nanocrystalline Materials, Pts 1 and 2, 1996, Vol. 225, pp. 853-858.
193. Zaluski, L., Zaluska, A., StromOlsen, J.O. Nanocrystalline metal hydrides. Journal of Alloys and Compounds 1997, 253, 70-79.
194. Zaluska, A., Zaluski, L., Strom-Olsen, J.O. Structure, catalysis and atomic reactions on the nano-scale: A systematic approach to metal hydrides for hydrogen storage. Applied Physics A: Materials Science & Processing 2001, 72(2), 157-165.
195. Sakintuna, B., Lamari-Darkrim, F., Hirscher, M. Metal hydride materials for solid hydrogen storage: A review. International Journal of Hydrogen Energy 2007, 32, 1121-1140.
196. Higuchi, K., Kajioka, H., Toiyama, K., Fujii, H., Orimo, S., Kikuchi, Y. In situ study of hydriding-dehydriding properties in some Pd/Mg thin films with different degree of Mg crystallization. Journal of Alloys and Compounds 1999, 295, 484-489.
197. Higuchi, K., Yamamoto, K., Kajioka, H., Toiyama, K., Honda, M., Orimo, S., Fujii, H. Remarkable hydrogen storage properties in three-layered Pd/Mg/Pd thin films. Journal of Alloys and Compounds 2002, 330, 526-530.
198. Akyildiz, H., Ozenbas, M., Ozturk, T. Hydrogen absorption in magnesium based crystalline thin films. International Journal of Hydrogen Energy 2006, 31(10), 1379-1383.
199. Wagemans, R.W.P., van Lenthe, J.H., de Jongh, P.E., van Dillen, A.J., de Jong, K.P. Hydrogen storage in magnesium clusters: Quantum chemical study. Journal of the American Chemical Society 2005, 127(47), 16675-16680.
200. He, Y.-P., Zhao, Y.-P. Hydrogen storage and cycling properties of Vanadium decorated Mg nanoblade array on Ti coated Si substrate. Nanotechnology 2009, 20, 204008.
201. Checchetto, R., Bazzanella, N., Miotello, A., Mengucci, P. Deuterium storage in Mg-Nb films. Journal of Alloys and Compounds 2005, 404, 461-464.
202. Huot, J., Liang, G., Boily, S., Van Neste, A., Schulz, R. Structural study and hydrogen sorption kinetics of ball-milled magnesium hydride. Journal of Alloys and Compounds 1999, 293, 495-500.
203. Berube, V., Dresselhaus, M.S., Chen, G. Entropy stabilization of deformed regions characterized by an excess volume for hydrogen storage applications. International Journal of Hydrogen Energy 2009, 34(4), 1862-1872.
204. Berube, V., Chen, G., Dresselhaus, M.S. Impact of nanostructuring on the enthalpy of formation of metal hydrides. International Journal of Hydrogen Energy 2008, 33(15), 4122-4131.
205. Kim, K.C., Dai, B., Johnson, J.K., Sholl, D.S. Assessing nanoparticle size effects on metal hydride thermodynamics using the Wulff construction. Nanotechnology 2009, 20(20).
206. Horvath, J., Birringer, R., Gleiter, H. Diffusion in nanocrystalline material. Solid State Communications 1987, 62(5), 319-322.
207. Frobose, K., Kolbe, F., Jackle, J. Size dependence of self-diffusion in a dense hard-disc liquid. Journal of Physics: Condensed Matter 2000, 12(29), 6563-6573.
208. Baddour, R.F., Iwasyk, J.M. Reactions between elemental carbon and hydrogen at temperatures above 2800 degrees K. Industrial & Engineering Chemistry Process Design and Development 1962, 1(3), 169-&.
209. Snelson, A. Reaction of atomic-hydrogen with carbon. Advances in Chemistry Series 1974, 131, 54-71.
210. Shimizu, T.K., Mugarza, A., Cerda, J.I., Salmeron, M. Structure and reactions of carbon and hydrogen on Ru(0001): A scanning tunneling microscopy study. Journal of Chemical Physics 2008, 129(24), 2441031-2441037.
211. Talyzin, A.V., Luzan, S., Anoshkin, I.V., Nasibulin, A.G., Jiang, H., Kauppinen, E.I., Mikoushkin, V.M., Shnitov, V.V., Marchenko, D.E., Noreus, D. Hydrogenation, purification, and unzipping of carbon nanotubes by reaction with molecular hydrogen: Road to graphane nanoribbons. ACS Nano 2011, 5(6), 5132-5140.
212. Wang, W., Wang, S.P., Ma, X.B., Gong, J.L. Recent advances in catalytic hydrogenation of carbon dioxide. Chemical Society Reviews 2011, 40(7), 3703-3727.
213. Chen, C.S., Wu, J.H., Lai, T.W. Carbon dioxide hydrogenation on Cu nanoparticles. Journal of Physical Chemistry C 2010, 114(35), 15021-15028.
214. 2. Journal of Catalysis 1997, 165(2), 129-139.
215. 2 catalysts. Physical Chemistry Chemical Physics 2000, 2(22), 5320-5327.
216. Arunajatesan, V., Subramaniam, B., Hutchenson, K.W., Herkes, F.E. In situ FTIR investigations of reverse water gas shift reaction activity at supercritical conditions. Chemical Engineering Science 2007, 62(18-20), 5062-5069.
217. Park, J.N., McFarland, E.W. A highly dispersed Pd-Mg/SiO2 catalyst active for methanation of CO2. Journal of Catalysis 2009, 266(1), 92-97.
218. Peebles, D.E., Goodman, D.W., White, J.M. Methanation of carbon-dioxide on Ni(100) and the effects of surface modifiers. Journal of Physical Chemistry 1983, 87(22), 4378-4387.
219. Marwood, M., Doepper, R., Renken, A., In-situ surface and gas phase analysis for kinetic studies under transient conditions: The catalytic hydrogenation of CO2. Applied Catalysis A: General 1997, 151(1), 223-246.
220. Lapidus, A.L., Gaidai, N.A., Nekrasov, N.V., Tishkova, L.A., Agafonov, Y.A., Myshenkova, T.N. The mechanism of carbon dioxide hydrogenation on copper and nickel catalysts. Petroleum Chemistry 2007, 47(2), 75-82.
221. Fujita, S., Terunuma, H., Kobayashi, H., Takezawa, N. Methanation of carbon-monoxide and carbon-dioxide over nickel-catalyst under the traisnet state. Reaction Kinetics and Catalysis Letters 1987, 33(1), 179-184.
222. Schild, C., Wokaun, A., Baiker, A. On the mechanim of CO and CO2 hydrogenation reactions on zirconia-supported catalysts: A diffuse reflectance FTIR study. 2. Surface species on copper zirconia catalysts: Implications for methanol synthesis selectivity. Journal of Molecular Catalysis 1990, 63(2), 243-254.
223. 2/CO ratios. Journal of Physical Chemistry B 2005, 109(6), 2432-2438.
224. 2 to methanol. Applied Catalysis a-General 2004, 278(1), 11-23.
225. 2. Journal of Catalysis 1997, 172(1), 222-237.
226. Niemann, M.U., Srinivasan, S.S., Phani, A.R., Kumar, A., Goswami, D.Y., Stefanakos, E.K. Nanomaterials for hydrogen storage applications: A review. Journal of Nanomaterials 2008, 1-9.
227. Lim, K.L., Kazemian, H., Yaakob, Z., Daud, W.R.W. Solid-state materials and methods for hydrogen storage: A critical review. Chemical Engineering & Technology 2010, 33(2), 213-226.
228. Sudan, P., Zuttel, A., Mauron, P., Emmenegger, C., Wenger, P., Schlapbach, L. Physisorption of hydrogen in single-walled carbon nanotubes. Carbon 2003, 41(12), 2377-2383.
229. Nijkamp, M.G., Raaymakers, J., van Dillen, A.J., de Jong, K.P. Hydrogen storage using physisorption: Materials demands. Applied Physics a-Materials Science & Processing 2001, 72(5), 619-623.
230. Dillon, A.C., Jones, K.M., Bekkedahl, T.A., Kiang, C.H., Bethune, D.S., Heben, M.J. Storage of hydrogen in single-walled carbon nanotubes. Nature 1997, 386(6623), 377-379.
231. Wu, H.M., Wexler, D., Liu, H. Effects of different palladium content loading on the hydrogen storage capacity of double-walled carbon nanotubes. International Journal of Hydrogen Energy 2012, 37(7), 5686-5690.
232. Tsai, P.J., Yang, C.H., Hsu, W.C., Tsai, W.T., Chang, J.K. Enhancing hydrogen storage on carbon nanotubes via hybrid chemical etching and Pt decoration employing supercritical carbon dioxide fluid. International Journal of Hydrogen Energy 2012, 37(8), 6714-6720.
233. Kroto, H.W., Heath, J.R., Obrien, S.C., Curl, R.F., Smalley, R.E. C-60: Buckminsterfullerene. Nature 1985, 318(6042), 162-163.
234. Peera, A.A., Alemany, L.B., Billups, W.E. Hydrogen storage in hydrofullerides. Applied Physics A: Materials Science & Processing 2004, 78(7), 995-1000.
235. Sun, Q., Jena, P., Wang, Q., Marquez, M. First-principles study of hydrogen storage on Li12C60. Journal of the American Chemical Society 2006, 128(30), 9741-9745.
236. Yoshida, A., Okuyama, T., Terada, T., Naito, S. Reversible hydrogen storage/release phenomena on lithium fulleride (LinC60) and their mechanistic investigation by solid-state NMR spectroscopy. Journal of Materials Chemistry 2011, 21(26), 9480-9482.
237. Paolone, A., Vico, F., Teocoli, F., Sanna, S., Palumbo, O., Cantelli, R., Knight, D.A., Teprovich, J.A., Zidan, R. Relaxation processes and structural changes in Li-and Na-Doped fulleranes for hydrogen storage. Journal of Physical Chemistry C 2012, 116(31), 16365-16370.
238. Teprovich, J.A., Wellons, M.S., Lascola, R., Hwang, S.J., Ward, P.A., Compton, R.N., Zidan, R. Synthesis and characterization of a lithium-doped fullerane (Li-x-C-60-H-y) for reversible hydrogen storage. Nano Letters 2012, 12(2), 582-589.
239. Elias, D.C., Nair, R.R., Mohiuddin, T.M.G., Morozov, S.V., Blake, P., Halsall, M.P., Ferrari, A.C., Boukhvalov, D.W., Katsnelson, M.I., Geim, A.K., Novoselov, K.S. Control of Graphene's properties by reversible hydrogenation: Evidence for graphane. Science 2009, 323(5914), 610-613.
240. Parambhath, V.B., Nagar, R., Ramaprabhu, S. Effect of nitrogen doping on hydrogen storage capacity of palladium decorated graphene. Langmuir 2012, 28(20), 7826-7833.
241. Xi, P.X., Chen, F.J., Xie, G.Q., Ma, C., Liu, H.Y., Shao, C.W., Wang, J., Xu, Z.H., Xu, X.M., Zeng, Z.Z. Surfactant free RGO/Pd nanocomposites as highly active heterogeneous catalysts for the hydrolytic dehydrogenation of ammonia borane for chemical hydrogen storage. Nanoscale 2012, 4(18), 5597-5601.
242. Zhang, F., Hou, C.Y., Zhang, Q.H., Wang, H.Z., Li, Y.G. Graphene sheets/cobalt nanocomposites as low-cost/high-performance catalysts for hydrogen generation. Materials Chemistry and Physics 2012, 135(2-3), 826-831.
243. Vinayan, B.P., Sethupathi, K., Ramaprabhu, S. Hydrogen storage studies of palladium decorated nitrogen doped graphene nanoplatelets. Journal of Nanoscience and Nanotechnology 2012, 12(8), 6608-6614.
244. Wu, M.H., Gao, Y., Zhang, Z.Y., Zeng, X.C. Edge-decorated graphene nanoribbons by scandium as hydrogen storage media. Nanoscale 2012, 4(3), 915-920.
245. Wang, V., Mizuseki, H., He, H.P., Chen, G., Zhang, S.L., Kawazoe, Y. Calcium-decorated graphene for hydrogen storage: A van der Waals density functional study. Computational Materials Science 2012, 55, 180-185.
246. Zhao, G.F., Li, Y., Liu, C.S., Wang, Y.L., Sun, J.M., Gu, Y.Z., Wang, Y.X., Zeng, Z. Boron nitride substrate-induced reversible hydrogen storage in bilayer solid matrix via interlayer spacing. International Journal of Hydrogen Energy 2012, 37(12), 9677-9687.
247. Zhou, W.W., Zhou, J.J., Shen, J.Q., Ouyang, C.Y., Shi, S.Q. First-principles study of high-capacity hydrogen storage on graphene with Li atoms. Journal of Physics and Chemistry of Solids 2012, 73(2), 245-251.
248. Cheng, H.M., Liu, C., Fan, Y.Y., Li, F., Su, G., Cong, H.T., He, L.L., Liu, M. Synthesis and hydrogen storage of carbon nanofibers and single-walled carbon nanotubes. Zeitschrift Fur Metallkunde 2000, 91(4), 306-310.
249. Wu, H.C., Li, Y.Y., Sakoda, A. Synthesis and hydrogen storage capacity of exfoliated turbostratic carbon nanofibers. International Journal of Hydrogen Energy 2010, 35(9), 4123-4130.
250. Jimenez, V., Ramirez-Lucas, A., Sanchez, P., Valverde, J.L., Romero, A. Improving hydrogen storage in modified carbon materials. International Journal of Hydrogen Energy 2012, 37(5), 4144-4160.
251. Tsao, C.S., Tzeng, Y.R., Yu, M.S., Wang, C.Y., Tseng, H.H., Chung, T.Y., Wu, H.C., Yamamoto, T., Kaneko, K., Chen, S.H. Effect of catalyst size on hydrogen storage capacity of Pt-impregnated active carbon via spillover. Journal of Physical Chemistry Letters 2010, 1(7), 1060-1063.
252. Noh, J.S., Agarwal, R.K., Schwarz, J.A. Hydrogen storage-systems using activated carbon. International Journal of Hydrogen Energy 1987, 12(10), 693-700.
253. Im, J.S., Park, S.J., Lee, Y.S. Superior prospect of chemically activated electrospun carbon fibers for hydrogen storage. Materials Research Bulletin 2009, 44(9), 1871-1878.
254. Sevilla, M., Mokaya, R., Fuertes, A.B. Ultrahigh surface area polypyrrole-based carbons with superior performance for hydrogen storage. Energy & Environmental Science 2011, 4(8), 2930-2936.
255. Zhao, W., Fierro, V., Zlotea, C., Izquierdo, M.T., Chevalier-Cesar, C., Latroche, M. Celzard, A., Activated carbons doped with Pd nanoparticles for hydrogen storage. International Journal of Hydrogen Energy 2012, 37(6), 5072-5080.
256. Yuan, S.W., Kirklin, S., Dorney, B., Liu, D.J., Yu, L.P. Nanoporous polymers containing stereocontorted cores for hydrogen storage. Macromolecules 2009, 42(5), 1554-1559.
257. Xiang, Z.H., Cao, D.P., Wang, W.C., Yang, W.T., Han, B.Y., Lu, J.M. Postsynthetic lithium modification of covalent-organic polymers for enhancing hydrogen and carbon dioxide storage. Journal of Physical Chemistry C 2012, 116(9), 5974-5980.
258. Figueroa-Torres, M.Z., Dominguez-Rios, C., Cabanas-Moreno, J.G., Vega-Becerra, O., Aguilar-Elguezabal, A. The synthesis of Ni-activated carbon nanocomposites via electroless deposition without a surface pretreatment as potential hydrogen storage materials. International Journal of Hydrogen Energy 2012, 37(14), 10743-10749.
259. Zhevago, N.K., Glebov, V.I. Hydrogen storage in capillary arrays. Energy Conversion and Management 2007, 48(5), 1554-1559.
260. Zhevago, N.K., Denisov, E.I., Glebov, V.I. Experimental investigation of hydrogen storage in capillary arrays. International Journal of Hydrogen Energy 2010, 35(1), 169-175.
261. Holtappels, K., Beckmann-Kluge, M., Gebauer, M., Eliezer, D. Pressure Resistance of Glass Capillaries for Hydrogen Storage. Materials Testing 2011, 53(1-2), 14-18.
262. Schmitt, M.L., Shelby, J.E., Hall, M.M. Preparation of hollow glass microspheres from sol-gel derived glass for application in hydrogen gas storage. Journal of Non-Crystalline Solids 2006, 352(6-7), 626-631.
263. Qi, X.B., Gao, C., Zhang, Z.W., Chen, S.F., Li, B., Wei, S. Production and characterization of hollow glass microspheres with high diffusivity for hydrogen storage. International Journal of Hydrogen Energy 2012, 37(2), 1518-1530.
264. Weitkamp, J., Fritz, M., Ernst, S. Zeolites as media for hydrogen storage. International Journal of Hydrogen Energy 1995, 20(12), 967-970.
265. Langmi, H.W., Book, D., Walton, A., Johnson, S.R., Al-Mamouri, M.M., Speight, J.D., Edwards, P.P., Harris, I.R., Anderson, P.A. Hydrogen storage in ion-exchanged zeolites. Journal of Alloys and Compounds 2005, 404, 637-642.
266. Dong, J.X., Wang, X.Y., Xu, H., Zhao, Q., Li, J.P. Hydrogen storage in several microporous zeolites. International Journal of Hydrogen Energy 2007, 32(18), 4998-5004.
267. Chung, K.H. High-pressure hydrogen storage on microporous zeolites with varying pore properties. Energy 2010, 35(5), 2235-2241.
268. Yang, G., Zhou, L.J., Liu, X.C., Han, X.W., Bao, X.H. Adsorption, reduction and storage of hydrogen within ZSM-5 zeolite exchanged with various ions: A comparative theoretical study. Microporous and Mesoporous Materials 2012, 161, 168-178.
269. Rosi, N.L., Eckert, J., Eddaoudi, M., Vodak, D.T., Kim, J., O'Keeffe, M., Yaghi, O.M. Hydrogen storage in microporous metal-organic frameworks. Science 2003, 300(5622), 1127-1129.
270. Wong-Foy, A.G., Matzger, A.J., Yaghi, O.M. Exceptional H-2 saturation uptake in microporous metal-organic frameworks. Journal of the American Chemical Society 2006, 128(11), 3494-3495.
271. Yan, Y., Lin, X., Yang, S.H., Blake, A.J., Dailly, A., Champness, N.R., Hubberstey, P., Schroder, M. Exceptionally high H-2 storage by a metal-organic polyhedral framework. Chemical Communications 2009, (9), 1025-1027.
272. Yang, S.J., Jung, H., Kim, T., Im, J.H., Park, C.R. Effects of structural modifications on the hydrogen storage capacity of MOF-5. International Journal of Hydrogen Energy 2012, 37(7), 5777-5783.
273. Yang, S.J., Kim, T., Im, J.H., Kim, Y.S., Lee, K., Jung, H., Park, C.R. MOF-Derived hierarchically porous carbon with exceptional porosity and hydrogen storage capacity. Chemistry of Materials 2012, 24(3), 464-470.
274. Mao, W.L., Mao, H.K. Hydrogen storage in molecular compounds. Proceedings of the National Academy of Sciences of the United States of America 2004, 101(3), 708-710.
275. Lee, H., Lee, J.W., Kim, D.Y., Park, J., Seo, Y.T., Zeng, H., Moudrakovski, I.L., Ratcliffe, C.I., Ripmeester, J.A. Tuning clathrate hydrates for hydrogen storage. Nature 2005, 434(7034), 743-746.
276. Su, F.B., Bray, C.L., Carter, B.O., Overend, G., Cropper, C., Iggo, J.A., Khimyak, Y.Z., Fogg, A.M., Cooper, A.I. Reversible hydrogen storage in hydrogel clathrate hydrates. Advanced Materials 2009, 21(23), 2382-2386.
277. Clawson, J.S., Cygan, R.T., Alam, T.M., Leung, K., Rempe, S.B. Ab initio study of hydrogen storage in water clathrates. Journal of Computational and Theoretical Nanoscience 2010, 7(12), 2602-2606.
278. Belosludov, R.V., Zhdanov, R.K., Subbotin, O.S., Mizuseki, H., Souissi, M., Kawazoe, Y., Belosludov, V.R. Theoretical modelling of the phase diagrams of clathrate hydrates for hydrogen storage applications. Molecular Simulation 2012, 38(10), 773-780.
279. Willow, S.Y., Xantheas, S.S. Enhancement of hydrogen storage capacity in hydrate lattices. Chemical Physics Letters 2012, 525-526, 13-18.
280. 2 reaction. Int. J. Chem. Kinetics 1999, 31, 113-125.
281. Li, J., Zhao, Z.W., Kazakov, A., Dryer, F.L. An updated comprehensive kinetic model of hydrogen combustion. International Journal of Chemical Kinetics 2004, 36(10), 566-575.
282. 2 (+M). Proc. Combust. Inst 2000, 28, 1463-1469.
283. Klell, M., Eichlseder, H., Sartory, M. Mixtures of hydrogen and methane in the internal combustion engine: Synergies, potential and regulations. International Journal of Hydrogen Energy 2012, 37(15), 11531-11540.
284. Frassoldati, A., Faravelli, T., Ranzi, E. A wide range modeling study of NOx formation and nitrogen chemistry in hydrogen combustion. International Journal of Hydrogen Energy 2006, 31(15), 2310-2328.
285. Rortveit, G.J., Hustad, J.E., Li, S.C., Williams, F.A. Effects of diluents on NOx formation in hydrogen counterflow flames. Combustion and Flame 2002, 130(1-2), 48-61.
286. Ayoub, M., Rottier, C., Carpentier, S., Villermaux, C., Boukhalfa, A.M., Honore, D. An experimental study of mild flameless combustion of methane/hydrogen mixtures. International Journal of Hydrogen Energy 2012, 37(8), 6912-6921.
287. Shimizu, K., Hibi, A., Koshi, M., Morii, Y., Tsuboi, N. Updated kinetic mechanism for high-pressure hydrogen combustion. Journal of Propulsion and Power 2011, 27(2), 383-395.
288. Stamps, D.W., Berman, M. High-temperature hydrogen combustion in reactor safety applications. Nuclear Science and Engineering 1991, 109(1), 39-48.
289. Sepman, A.V., Mokhov, A.V., Levinsky, H.B. Extending the predictions of chemical mechanisms for hydrogen combustion: Comparison of predicted and measured flame temperatures in burner-stabilized, 1-D flames. International Journal of Hydrogen Energy 2011, 36(15), 9298-9303.
290. Haruta, M., Sano, H. Catalytic combustion of hydrogen 1: Its role in hydrogen utilization system and screening of catalyst materials. International Journal of Hydrogen Energy 1981, 6(6), 601-608.
291. Haruta, M., Souma, Y., Sano, H. Catalytic combustion of hydrogen 2: An experimental investigation of fundamental conditions for burner design. International Journal of Hydrogen Energy 1982, 7(9), 729-736.
292. 4 mesoporous coating monolithic catalyst. International Journal of Hydrogen Energy 2012, 37(17), 12941-12946.
293. Deshpande, P.A., Polisetti, S., Madras, G., Analysis of oxide and vanadate supports for catalytic hydrogen combustion: Kinetic and mechanistic investigations. Aiche Journal 2012, 58(3), 932-945.
294. Pollet, B.G., Staffell, I., Shang, J.L. Current status of hybrid, battery and fuel cell electric vehicles: From electrochemistry to market prospects. Electrochimica Acta 2012, 84, 235-249.
295. Smil, V. Tomorrow's energy: Hydrogen, fuel cells, and the prospects for a cleaner planet. Environment and Planning A 2002, 34(12), 2260-2261.
296. Friedrich, K.A., Fuel Cells. Bwk 2012, 64(4), 110-116.
297. Carrette, L., Friedrich, K.A., Stimming, U. Fuel cells: fundamentals and applications. Fuel Cells 2001, 1(1), 5-39.
298. Carrette, L., Friedrich, K.A., Stimming, U. Fuel cells: Principles, types, fuels, and applications. Chemphyschem 2000, 1(4), 162-193.
299. Cao, D.X., Sun, Y., Wang, G.L. Direct carbon fuel cell: Fundamentals and recent developments. Journal of Power Sources 2007, 167(2), 250-257.
300. Wang, Y., Chen, K.S., Mishler, J., Cho, S.C., Adroher, X.C. A review of polymer electrolyte membrane fuel cells: Technology, applications, and needs on fundamental research. Applied Energy 2011, 88(4), 981-1007.
301. Sun, S., Jusys, Z., Behm, R.J. Electrooxidation of ethanol on Pt-based and Pd-based catalysts in alkaline electrolyte under fuel cell relevant reaction and transport conditions. Journal of Power Sources 2013, 231, 122-133.
302. Stoica, D., Ogier, L., Akrour, L., Alloin, F., Fauvarque, J.F. Anionic membrane based on polyepichlorhydrin matrix for alkaline fuel cell: Synthesis, physical and electrochemical properties. Electrochimica Acta 2007, 53(4), 1596-1603.
303. Lee, S.M., Kim, J.H., Lee, H.H., Lee, P.S., Lee, J.Y. The characterization of an alkaline fuel cell that uses hydrogen storage alloys. Journal of the Electrochemical Society 2002, 149(5), A603-A606.
304. Wang, J.H., Li, S.H., Zhang, S.B. Novel hydroxide-conducting polyelectrolyte composed of an poly(arylene ether sulfone) containing pendant quaternary guanidinium groups for alkaline fuel cell applications. Macromolecules 2010, 43(8), 3890-3896.
305. Adams, L.A., Poynton, S.D., Tamain, C., Slade, R.C.T., Varcoe, J.R. A carbon dioxide tolerant aqueous-electrolyte-free anion-exchange membrane alkaline fuel cell. Chemsuschem 2008, 1(1-2), 79-81.
306. Sanchez, D.G., Hiesgen, R., Wehl, I., Friedrich, K.A. Correlation of oscillation of polymer electrolyte membrane fuel cells at low cathode humidification with nanoscale membrane properties. Batteries and Energy Technology (General): 219th Ecs Meeting 2011, 35(32), 41-54.
307. Gulzow, E., Schulze, M., Friedrich, K.A., Fischer, P., Bettermann, H. Local in-Situ Analysis of Pem Fuel Cells by Impedance Spectroscopy and Raman Measurements. Fuel Cell Seminar 2010 2011, 30(1), 65-76.
308. Sanchez, D.G., Diaz, D.G., Hiesgen, R., Wehl, I., Friedrich, K.A. Oscillations of PEM fuel cells at low cathode humidification. Journal of Electroanalytical Chemistry 2010, 649(1-2), 219-231.
309. Zhang, S.S., Yuan, X.Z., Hin, J.N.C., Wang, H.J., Friedrich, K.A., Schulze, M. A review of platinum-based catalyst layer degradation in proton exchange membrane fuel cells. Journal of Power Sources 2009, 194(2), 588-600.
310. Silveira, J.L., Leal, E.M., Ragonha, L.F. Analysis of a molten carbonate fuel cell: cogeneration to produce electricity and cold water. Energy 2001, 26(10), 891-904.
311. Schulze, M., Gulzow, E., Friedrich, K.A. Low pressure test facility for polymer electrolyte membrane fuel cells and first measurements. Fuel Cell Seminar 2007 2008, 12(1), 187-197.
312. Costamagna, P., Srinivasan, S. Quantum jumps in the PEMFC science and technology from the 1960s to the year 2000: Part II. Engineering, technology development and application aspects. Journal of Power Sources 2001, 102(1-2), 253-269.
313. Oezaslan, M., Hasche, F., Strasser, P. Oxygen electroreduction on PtxCo1-x and PtxCu1-x alloy nanoparticles for basic and acidic pem fuel cell. Polymer Electrolyte Fuel Cells 11 2011, 41(1), 1659-1668.
314. Hasche, F., Fellinger, T.P., Oezaslan, M., Paraknowitsch, J.P., Antonietti, M., Strasser, P. Mesoporous nitrogen doped carbon supported platinum PEM fuel cell electrocatalyst made from ionic liquids. Chemcatchem 2012, 4(4), 479-483.
315. Hasche, F., Oezaslan, M., Strasser, P. Activity, Stability, and degradation mechanisms of dealloyed PtCu3 and PtCo3 nanoparticle fuel cell catalysts. Chemcatchem 2011, 3(11), 1805-1813.
316. Strasser, P. Fuel cell catalyst particles have platinum-rich shell, copper core. Advanced Materials & Processes 2008, 166(1), 13-13.
317. Strasser, P. Dealloyed core-shell fuel cell electrocatalysts. Reviews in Chemical Engineering 2009, 25(4), 255-295.
318. Wang, Y.J., Wilkinson, D.P., Zhang, J.J. Noncarbon support materials for polymer electrolyte membrane fuel cell electrocatalysts. Chemical Reviews 2011, 111(12), 7625-7651.
319. Debe, M.K. Electrocatalyst approaches and challenges for automotive fuel cells. Nature 2012, 486(7401), 43-51.
320. Mani, P., Srivastava, R., Strasser, P. Dealloyed Pt-Cu core-shell nanoparticle electrocatalysts for use in PEM fuel cell cathodes. Journal of Physical Chemistry C 2008, 112(7), 2770-2778.
321. Srivastava, R., Mani, P., Hahn, N., Strasser, P. Efficient oxygen reduction fuel cell electrocatalysis on voltammetrically dealloyed Pt-Cu-Co nanoparticles. Angewandte Chemie-International Edition 2007, 46(47), 8988-8991.
322. Stonehart, P. Development of advanced noble metal-alloy electrocatalysts for phosphoric-acid fuel-cells (PAFC). Berichte Der Bunsen-Gesellschaft-Physical Chemistry Chemical Physics 1990, 94(9), 913-921.
323. Ganguly, S., Das, S., Kargupta, K., Bannerjee, D. Optimization of performance of phosphoric acid fuel cell (PAFC) Stack using reduced order model with integrated space marching and electrolyte concentration inferencing. 11th International Symposium on Process Systems Engineering, Pts A and B 2012, 31, 1010-1014.
324. Watanabe, M., Tsurumi, K., Mizukami, T., Nakamura, T., Stonehart, P. Activity and stability of ordered and disordered Co-Pt alloys for phosphoric-acid fuel-cells. Journal of the Electrochemical Society 1994, 141(10), 2659-2668.
325. Zhang, H.C., Lin, G.X., Chen, J.C., Multi-objective optimisation analysis and load matching of a phosphoric acid fuel cell system. International Journal of Hydrogen Energy 2012, 37(4), 3438-3446.
326. Zhang, H.S., Wang, L.J., Weng, S.L., Su, M. Control performance study on the molten carbonate fuel cell hybrid systems. Proceedings of the Asme Turbo Expo 2008, 2, 611-618.
327. Antolini, E. The stability of molten carbonate fuel cell electrodes: A review of recent improvements. Applied Energy 2011, 88(12), 4274-4293.
328. Bychin, V.P., Zvezdkin, M.A., Samatov, O. M. Porous nickel anode for molten-carbonate electrolyte fuel-cell. Russian Journal of Electrochemistry 1993, 29(11), 1173-1176.
329. Zhao, M.S., Sun, C.Y. A novel anode material for molten carbonate fuel cell. Proceedings of the 6th International Symposium on Molten Salt Chemistry and Technology 2001, 402-408.
330. Batra, V.S., Maudgal, S., Bali, S., Tewari, P.K. Development of alpha lithium aluminate matrix for molten carbonate fuel cell. Journal of Power Sources 2002, 112(1), 322-325.
331. Baumgartner, C.E. NiO Solubility in molten Li/K carbonate under molten carbonate fuel-cell cathode environments. Journal of the Electrochemical Society 1984, 131(8), 1850-1851.
332. Travis, R.P., Hart, J., Costamagna, P., Agnew, G.D., Attia, O. Fuel cell system reliability for a pressurised integrated-plannar SOFC. Proceedings of the 3rd International Conference on Fuel Cell Science, Engineering, and Technology 2005, 335-340.
333. Gemmen, R., Abernathy, H., Gerdes, K., Koslowske, M., McPhee, W.A., Tao, T. Fundamentals of liquid tin anode solid oxide fuel cell (Lta-Sofc) operation. Advances in Solid Oxide Fuel Cells V 2010, 30(4), 37-52.
334. Costamagna, P., Costa, P., Antonucci, V. Micro-modelling of solid oxide fuel cell electrodes. Electrochimica Acta 1998, 43(3-4), 375-394.
335. Magistri, L., Trasino, F., Costamagna, P. Transient analysis of solid oxide fuel cell hybrids -Part I: Fuel cell models. Journal of Engineering for Gas Turbines and Power-Transactions of the Asme 2006, 128(2), 288-293.
336. Costamagna, P., Magistri, L., Massardo, A.F. Design and part-load performance of a hybrid system based on a solid oxide fuel cell reactor and a micro gas turbine. Journal of Power Sources 2001, 96(2), 352-368.
337. Costamagna, P., Selimovic, A., Del Borghi, M., Agnew, G. Electrochemical model of the integrated planar solid oxide fuel cell (IP-SOFC). Chemical Engineering Journal 2004, 102(1), 61-69.
338. Mabena, L.F., Modibedi, R.M., Ray, S.S., Coville, N.J. Ruthenium supported on nitrogen-doped carbon nanotubes for the oxygen reduction reaction in alkaline media. Fuel Cells 2012, 12(5), 862-868.
339. Sidik, R.A., Anderson, A.B. Co9S8 as a catalyst for electroreduction of O2: Quantum chemistry predictions. Journal of Physical Chemistry B 2006, 110(2), 936-941.
340. Morozan, A., Jousselme, B., Palacin, S. Low-platinum and platinum-free catalysts for the oxygen reduction reaction at fuel cell cathodes. Energy & Environmental Science 2011, 4(4), 1238-1254.
341. Zhang, J., Sasaki, K., Sutter, E., Adzic, R.R. Stabilization of platinum oxygen-reduction electrocatalysts using gold clusters. Science 2007, 315(5809), 220-222.
342. Bing, Y.H., Liu, H.S., Zhang, L., Ghosh, D., Zhang, J.J. Nanostructured Pt-alloy electrocatalysts for PEM fuel cell oxygen reduction reaction. Chemical Society Reviews 2010, 39(6), 2184-2202.
343. Peng, Z.M., Yang, H., Synthesis and oxygen reduction electrocatalytic property of Pt-on-Pd bimetallic heteronanostructures. Journal of American Chemical Society 2009, 131, 7542-7543.
344. Collman, J.P., Devaraj, N.K., Decreau, R.A., Yang, Y., Yan, Y.L., Ebina, W., Eberspacher, T.A., Chidsey, C.E.D. A cytochrome c oxidase model catalyzes oxygen to water reduction under rate-limiting electron flux. Science 2007, 315(5818), 1565-1568.
345. Gao, M.R., Jiang, J., Yu, S.H. Solution-based synthesis and design of late transition metal chalcogenide materials for oxygen reduction reaction (ORR). Small 2012, 8(1), 13-27.
346. Wu, G., More, K.L., Johnston, C.M., Zelenay, P. High-Performance electrocatalysts for oxygen reduction derived from polyaniline, iron, and cobalt. Science 2011, 332(6028), 443-447.
347. Gong, K.P., Du, F., Xia, Z.H., Durstock, M., Dai, L.M. Nitrogen-doped carbon nanotube arrays with high electrocatalytic activity for oxygen reduction. Science 2009, 323(5915), 760-764.
348. Liang, Y.Y., Li, Y.G., Wang, H.L., Zhou, J.G., Wang, J., Regier, T., Dai, H.J. Co3O4 nanocrystals on graphene as a synergistic catalyst for oxygen reduction reaction. Nature Materials 2011, 10(10), 780-786.
349. Schlapbach, L., Zuttel, A. Hydrogen-storage materials for mobile applications. Nature 2001, 414(6861), 353-358.
350. Ahmed, S., Krumpelt, M. Hydrogen from hydrocarbon fuels for fuel cells. International Journal of Hydrogen Energy 2001, 26(4), 291-301.
351. Friedrich, K.A., Kallo, J., Schirmer, J. Fuel cells for aircraft application. ICNMM 2009, Pts A-B 2009, 1231-1240.
352. Dyer, C.K. Fuel cells for portable applications. Journal of Power Sources 2002, 106(1-2), 31-34.
353. Ahn, S.Y., Eom, S.Y., Rhie, Y.H., Sung, Y.M., Moon, C.E., Choi, G.M., Kim, D.J. Application of refuse fuels in a direct carbon fuel cell system. Energy 2013, 51, 447-456.
354. Finsterwolder, F. Where goes the drive? Fuel cell-component for the automobile. Bwk 2008, 60(1-2), S8-S9.
355. Harvey, D. The fuel cell for the automobile: Some deflating truths. Tce 2004, (760), 34-36.
356. Heinzel, A., Hebling, C., Zedda, M. Fuel cells with restricted performances for portable applications. Stationary Fuel Cell Power Plants: Commercialization 2001, 1596, 97-106.
357. Trimm, D.L., Onsan, Z.I. Onboard fuel conversion for hydrogen-fuel-cell-driven vehicles. Catalysis Reviews: Science and Engineering 2001, 43(1-2), 31-84.
358. Li, Z.F. Research on energy management strategy of fuel cell/battery hybrid electric automobile. ICMET 09: Proceedings of the 2009 International Conference on Mechanical and Electrical Technology 2009, 61-64.
359. Scherzer, J., Gruia, A.J. Hydrocracking Science and Technology, CRC Press, New York, 1996.
360. Ward, J.W. Hydrocracking processes and catalysts. Fuel Process Technology, 1993, 35(1-2), 55-85.
361. Weitkamp, J. Catalytic hydrocracking-mechanisms and versatility of the process. ChemCatChem, 2012, 4(3), 292-306.
362. Belokopytov, Y. Reaction mechanism in hydrogenolysis of chlorobenzene over nickel-chromium catalyst. Theoretical and Experimental Chemistry, 1998, 34(5), 280-282.
363. Bučko, T., Benco, L., Hafner, J., Ángyán, J.G. Monomolecular cracking of propane over acidic chabazite: An ab initio molecular dynamics and transition path sampling study. Journal of Catalysis, 2011, 279(1), 220-228.
364. Babitz, S.M., Williams, B.A., Miller, J.T., Snurr, R.Q., Haag, W.O., Kung, H.H. Monomolecular cracking of n-hexane on Y, MOR, and ZSM-5 zeolites. Applied Catalysis A: General, 1999, 179(1-2), 71-86;
365. Chang, F.X., Wei, Y.X., Liu, X.B., Zhao, Y.F., Xu, L., Sun, Y., Zhang, D.Z., He, Y.L., Liu, Z.M. A mechanistic investigation of the coupled reaction of n-hexane and methanol over HZSM-5. Applied Catalysis A: General, 2007, 328(2), 163-173.
366. Kotrel, S., Knozinger, H., Gates, B.C. The Haag-Dessau mechanism of protolytic cracking of alkanes. Microporous and Mesoporous Materials, 2000, 35-36, 11-20.
367. He, K., Zhang, S., Mi, J., Chen, J., Cheng, L. Mechanism of catalytic hydropyrolysis of sedimentary organic matter with MoS2. Petroleum Science, 2011, 8(2), 134-142.
368. Ramachandran, R., Menon, R.K. An overview of industrial uses of hydrogen. International Journal of Hydrogen Energy, 1998, 23(7), 593-598.
369. Appl, M., Ammonia, 1. Introduction, Wiley Publication, 2011.
370. Howard, F., James, H. Chemical Reactor Design: For Process Plants. In Case Study 106: Ammonia Synthesis, Austin, TX, John Wiley & Sons, 1977.
371. Lindlar, H., Dubuis, R. Palladium catalyst for partial reduction of acetylenes. Organic Syntheses, 1973, 5, 880.
372. Freeman, I.P. Margarines and Shortenings, Wiley Publication, 2000.
373. Breck, G., Bhatia, S. Handbook of Industrial Oil and Fat Products, CBS Publication, Delhi, 2008.
374. Luidold, S., Antrekowitsch, H. Hydrogen as a reducing agent: State-of-the-art science and technology. Jom, 2007, 59(6), 20-26.
375. Wiley-VCH, Ullmann's Encyclopedia of Industrial Chemistry, 6th ed., Wiley Publication, Weinheim, 2003, Vol. 37.
376. Schulmeyer, W.V., Ortner, H.M. Mechanisms of the hydrogen reduction of molybdenum oxides. International Journal of Refractory Metals & Hard Materials, 2002, 20(4), 261-269.
377. Suban, M., Tusek, J., Uran, M. Use of hydrogen in welding engineering in former times and today. Journal of Materials Processing Technology, 2001, 119(1-3), 193-198.
378. Tusek, J., Suban, M. Experimental research of the effect of hydrogen in argon as a shielding gas in arc welding of high-alloy stainless steel. International Journal of Hydrogen Energy, 2000, 25(4), 369-376.
379. Nagano, S. Development of world's largest hydrogen-cooled turbine generator. Power Engineering Society Summer Meeting, IEEE, 2002, 2, 657-663.
380. Ahmed, Z., Ahmet, Z., Amro, M. Cooling Aerospace plane using hydrogen, ammonia and krypton. In 32nd Thermophysics Conference, American Institute of Aeronautics and Astronaulics, Inc., 1997.
381. Algarni, A.Z., Sahin, A.Z., Yilbas, B.S., Ahmed, S.A. Cooling of Aerospace Plane Using Liquid-Hydrogen and Methane. Journal of Aircraft, 1995, 32(3), 539-546.
382. Ford, P.J. The Rise of Superconductors, CRC Press, Boca Raton, FL, 2005.
383. Hirabayashi, H., Makida, Y., Nomura, S., Shintomi, T. Feasibility of hydrogen cooled superconducting magnets. Applied Superconductivity, IEEE Transactions, 2006, 16(2), 1435-1438.
384. Yamashita, S., Hotate, K. Multiwavelength erbium-doped fibre laser using intracavity etalon and cooled by liquid nitrogen, Electronics Letters, 1996, 32(14), 1298-1299.
385. Bednorz, J.G., Muller, K.A. Possible highT c superconductivity in the Ba-La-Cu-O system, Zeitschrift fur Physik B-Condensed Matter, 1986, 64(2), 189-193.
386. Kobayashi, S., Kaneko, T., Kato, T., Fujikami, J., Sato, K. A novel scaling of magnetic field dependencies of critical currents for Ag-sheathed Bi-2223 superconducting tape. Physica C: Superconductivity, 1996, 258(3-4), 336-340.
387. Van de Walle, C.G., Neugebauer, J. Universal alignment of hydrogen levels in semiconductors, insulators and solutions. Nature, 2003, 423(6940), 626-628.
388. Van de Walle, C.G., Neugebauer, J. Hydrogen in Semiconductors. Annual Review of Materials Research, 2006, 36(1), 179-198.
389. Neugebauer, J., Van de Walle, C. Hydrogen in GaN: Novel Aspects of a Common Impurity. Physical Review Letters, 1995, 75(24), 4452-4455.
390. Myers, S.M., Wright, A.F., Petersen, G.A., Seager, C.H., Wampler, W.R., Crawford, M.H., Han, J. Equilibrium state of hydrogen in gallium nitride: Theory and experiment. Journal of Applied Physics, 2000, 88(8), 4676-4687.
391. Van de Walle, C.G. Hydrogen as a cause of doping in zinc oxide. Physical Review Letters, 2000, 85, (5), 1012-1015.
392. Yang, P., Xiao, X., Li, Y., Ding, Y., Qiang, P., Tan, X., Mai, W., Lin, Z., Wu, W., Li, T., Jin, H., Liu, P., Zhou, J., Wong, C.P., Wang, Z.L. Hydrogenated ZnO Core-Shell Nanocables for Flexible Supercapacitors and Self-Powered Systems. ACS Nano, 2013, 7(3), 2617-26.
393. Hofmann, D.M., Hofstaetter, A., Leiter, F., Zhou, H.J., Henecker, F., Meyer, B.K., Orlinskii, S.B., Schmidt, J., Baranov, P.G. Hydrogen: A relevant shallow donor in zinc oxide. Physical Review Letters, 2002, 88(4), 045504.