Environmental Engineering Reference
In-Depth Information
53. Rostrup-Nielsen JR (2000) New aspects of syngas production and use. Catal Today
63:159-164
54. Stiegel GJ, Ramezan M (2006) Hydrogen from coal gasification: an economical pathway to
a sustainable energy future. Int J Coal Geol 65:173-190
55. Joshi MM, Lee S (1996) Integrated gasification combined cycle—a review of IGCC
technology. Energy Source 18:537-568
56. Damen K, van Troost M, Faaij A, Turkenburg W (2006) A comparison of electricity and
hydrogen production systems with CO
2
capture and storage. Part A: review and selection of
promising conversion and capture technologies. Prog Energy Combust 32:215-246
57. Cormos CC, Starr F, Tzimas E, Peteves S (2008) Innovative concepts for hydrogen
production processes based on coal gasification with CO2 capture. Int J Hydrogen Energ
33:1286-1294
58. Bohm MC, Herzog HJ, Parsons JE, Sekar RC (2007) Capture-ready coal plants—options,
technologies and economics. Int J Greenh Gas Control 1:113-120
59. Galvita V, Messerla VE, Urtimenko AB (2007) Hydrogen production by coal plasma
gasification for fuel cell technology. Int J Hydrogen Energ 32:3899-3906
60. Saxena RC, Seal D, Kumar S, Goyal HB (2008) Thermo-chemical routes for hydrogen rich
gas from biomass: a review. Renew Sust Energy Rev 12:1909-1927
61. Orecchini F, Bucci E (2007) Biomass to hydrogen for the realization of closed cycles of
energy resources. Energy J 32:1006-1011
62. Florin N, Harris A (2007) Hydrogen production from biomass. Environmentalist 27:207-215
63. Koroneos C, Dompros A, Roumbas G (2008) Hydrogen production via biomass gasi-
fication—a life cycle assessment approach. Chem Eng Process 47:1261-1268
64. Devi L, Ptasinski KJ, Janssen FJJG (2003) A review of the primary measures for tar
elimination in biomass gasification processes. Biomass Bioenerg 24:125-140
65. Bangala DN, Abatzoglou N, Martin JP, Chornet E (1997) Catalytic gas conditioning:
application to biomass and waste gasification. Ind Eng Chem Res 36:4184-4192
66. Koros W, Mahajan R (2000) Pushing the limits on possibilities for large scale gas
separation: which strategies? J Membr Sci 175:181-196
67. Abanades S, Charvin P, Flamant G, Neveu P (2006) Screening of water-splitting ther-
mochemical cycles potentially attractive for hydrogen production by concentrated solar
energy. Energy J 31:2805-2822
68. Lattin WC, Utgikar VP (2009) Global warming potential of the sulfur-iodine process using
life cycle assessment methodology. Int J Hydrogen Energ 34:737-744
69. Orhan MF, Dincer I, Rosen MA (2008) Energy and exergy assessments of the hydrogen
production step of a copper-chlorine thermochemical water splitting cycle driven by
nuclear-based heat. Int J Hydrogen Energ 33:6456-6466
70. Engelhardt V (1904) The electrolysis of water; processes and applications. Chemical
Publishing Company, Easton
71. Pletcher D, Walsh FC (1990) Industrial electrochemistry, 2nd edn. Kluwer, Dordrecht,
London, p 256
72. Rosen MA, Scott D (1998) Comparative efficiency assessments for a range of hydrogen
production processes. Int J Hydrogen Energ 23:653-659
73. Hall DE (1981) Electrodes for alkaline water electrolysis. J Electrochem Soc 128:740
74. Dyer CK (1985) Improved nickel anodes for industrial water electrolyzers. J Electrochem
Soc 132:64
75. Rami A, Lasia A (1992) Kinetics of hydrogen evolution on Ni-Al alloy electrodes. J Appl
Electrochem 22:376-382
76. Barbir F (2005) PEM electrolysis for production of hydrogen from renewable energy
sources. Sol Energy 78:661-669
77. Sherif SA, Barbir F, Veziroglu TN (2005) Wind energy and the hydrogen economy—review
of the technology. Sol Energy 78:647-660
78. Schiller G, Ansar A, Lang M, Patz O (2009) High temperature water electrolysis using
metal supported solid oxide electrolyser cells (SOEC). J Appl Electrochem 39:293-301
