Environmental Engineering Reference
In-Depth Information
79. Millet P, Andolfatto F, Durand R (1996) Design and performance of a solid polymer
electrolyte water electrolyzer. Int J Hydrogen Energ 21:87-93
80. Marshall A, Borresen B, Hagen G, Tsypkin M, Tunold R (2007) Hydrogen production by
advanced
proton
exchange
membrane
(PEM)
water
electrolysers—reduced
energy
consumption by improved electrocatalysis. Energy J 32:431-436
81. Grigoriev SA, Porembsky VI, Fateev VN (2006) Pure hydrogen production by PEM
electrolysis for hydrogen energy. Int J Hydrogen Energ 31:171-175
82. Onda K, Kyakuno T, Hattori K, Ito K (2004) Prediction of production power for high-
pressure water electrolysis. J Power Sources 132:64-70
83. Marangio F, Santarelli M, Calì M (2009) Theoretical model and experimental analysis of a
high pressure PEM water electrolyser for hydrogen production. Int J Hydrogen Energ
34:1143-1158
84. Grigoriev SA, Millet P, Fateev VN (2008) Evaluation of carbon-supported Pt and Pd
nanoparticles for the hydrogen evolution reaction in PEM water electrolysers. J Power
Sources 177:281-285
85. Granovskii M, Dincer I, Rosen MA (2006) Life cycle assessment of hydrogen fuel cell and
gasoline vehicles. Int J Hydrogen Energ 31:337-352
86. Jorgensen
C,
Ropenus
S
(2008)
Production
price
of
hydrogen
from
grid
connected
electrolysis
in
a
power
market
with
high
wind
penetration.
Int
J
Hydrogen
Energ
33:5335-5344
87. Mingyi L, Bo Y, Jingming X, Jing C (2008) Thermodynamic analysis of the efficiency of
high-temperature steam electrolysis system for hydrogen production. J Power Sources
177:493-499
88. Ni M, Leung MKH, Leung DYC (2008) Technological development of hydrogen production
by solid oxide electrolyser cell (SOEC). Int J Hydrogen Energ 33:2337-2354
89. Fujiwara S, Kasai S, Yamauchi H, Yamada K, Makino S, Matsunaga K, Yoshino M,
Kameda
T,
Ogawa
T,
Momma
S,
Hoashi
E
(2008)
Hydrogen
production
by
high
temperature electrolysis with nuclear reactor. Prog Nucl Energy 50:422-426
90. Coughlin RW, Farooque M (1980) Consideration of electrodes and electrolytes for
electrochemical gasification of coal by anodic oxidation. J Appl Electrochem 10:729-740
91. Sathe N, Botte GG (2006) Assessment of coal and graphite electrolysis on carbon fiber
electrodes. J Power Sources 161:513-523
92. Jin X, Botte GG (2007) Feasibility of hydrogen production from coal electrolysis at
intermediate temperatures. J Power Sources 171:826-834
93. Fujishima A, Honda K (1972) Electrochemical photolysis of water at a semiconductor
electrode. Nature 238:37-38
94. Penner SS (2006) Steps toward the hydrogen economy. Energy J 31:33-43
95. Bak T, Nowotny J, Rekas M, Sorrell CC (2002) Photo-electrochemical hydrogen generation
from water using solar energy. Materials-related aspects. Int J Hydrogen Energ 27:991-1022
96. Ni M, Leung MKH, Leung DHC, Sumathy K (2007) A review and recent developments in
photocatalytic water-splitting using TiO2 for hydrogen production. Renew Sust Energy Rev
11:401-425
97. Kelly NA, Gibson TL (2008) Solar energy concentrating reactors for hydrogen production
by photoelectrochemical water splitting. Int J Hydrogen Energ 33:6420-6431
98. Burgess G, Velasco JGF (2007) Materials, operational energy inputs, and net energy ratio
for photobiological hydrogen production. Int J Hydrogen Energ 32:1225-1234
99. Kapdan IK, Kargi F (2006) Bio-hydrogen production from waste materials. Enzyme Microb
Technol 38:569-582
100. Moore RB, Raman V (1998) Hydrogen infrastructure for fuel cell transportation. Int J
Hydrogen Energ 23:617-620
101. Haeseldonckx D, D'haeseleer W (2007) The use of the natural-gas pipeline infrastructure
for hydrogen transport in a changing market structure. Int J Hydrogen Energ 32:1381-1386
102. Padro C, Putsche V (1999) Survey of the economics of hydrogen technologies. DOE
National Renewable Energy Laboratory Report no. NREL/TP-570-27079, September
