您正在看的能源动力论文是:可再生氢能应用前景 -- 氢的制取。 ton P, Larson R, Nicklas M, Collins B. Renewable Hydrogen Forum: A summary
of eXPert opinions and policy recommendations [Z], National Press Club, Washington DC,
October 1, 2003.
[6] Wen Feng, Shujuan Wang, Weidou Ni, Changhe Chen, The future of hydrogen
infrastructure for fuel cell vehicles in China and a case of application in Beijing [J],
International Journal of Hydrogen Energy 2004, article in press.
[7] Rosa V.M, Santos M.B.F, Silva E.P.D, New materials for water electrolysis diaphragms
[J], International Journal of Hydrogen Energy 1995, 20(9): 697-700.
[8] Vermeiren P, Adriansens W, Moreels J.P, Leysen R. Evaluation of the zirfon separator for
use in alkaline water electrolysis and Ni-H2 batteries [J], International Journal of Hydrogen
Energy 1998, 23(5): 321-324.
[9] Hu W.K, Cao X.J, Wang F.P, Zhang Y.S. Short Communication: a novel cathode for
alkaline water electrolysis [J], International Journal of Hydrogen Energy 1997,22: 441-443.
[10] Schiller G, Henne R, Mohr P, Peinecke V. High performance electrodes for an advanced
intermittently operated 10-kW alkaline water electrolyzer [J], International Journal of
Hydrogen Energy 1998,23: 761-765.
[11] Hijikata T. Research and development of international clean energy network using
hydrogen energy (WE-NET) [J], International Journal of Hydrogen Energy2002, 27(2):
115-129.
[12] Kumar G.S, Raja M, Parthasarathy S. High performance electrodes with very low
platinum loading for polymer electrolyte fuel cells [J], Electrochimica Acta 1995, 40(3):
285-290.
[13] Hirano S, Kim J, Srinivasan S. High performance proton exchange membrane fuel cells
with sputter-deposited Pt layer electrodes [J], Electrochimica Acta 1997, 42(10): 1587-1593.
[14] Hayre R, Lee S.J, Cha S.W, Prinz F.B. A sharp peak in the performance of sputtered
platinum fuel cells at ultra-low platinum loading [J], Journal of Power Sources 2002, 109(2):
483-493.
[15] Guo Q.H, Pintauro P.N, Tang H, Connor S. Sulfonated and crosslinked
polyphosphazene-based proton-exchange membranes [J], Journal of Membrane Science 1999,
154(2): 175-181.
[16] Carretta N, Tricoli V, Picchioni F. Ionomeric membranes based on partially sulfonated
poly(styrene) synthesis, proton conduction and methanol permeation [J], Journal of
Membrane Science 2000, 166(2):189-197.
[17] Ghany N.A.A, Kumagai N, Meguro S, Asami K, Hashimoto K, Oxygen evolution anodes
composed of anodically deposited Mn-Mo-Fe oxides for seawater electrolysis [J],
Electrochimica Acta 2002, 48(1): 21-28.
[18] Green MA, Recent developments in photovoltaics [J], Solar Energy 2004, 76(1): 3-8.
[19] Ackermann T, Soder L, An overview of wind energy-status 2002 [J], Renewable and
Sustainable Energy Reviews 2002, 6(1): 67-128.
[20] Padro C.E.G, Putsche V. Survey of the economics of hydrogen technologies [Z],
NREL/TP-570-27079, September 1999, National Renewable Energy Laboratory, U.S.A.
[21] Kogan A, Direct solar thermal splitting of water and on site separation of the products 1:
theoretical evaluation of hydrogen yield [J], International Journal of Hydrogen Energy 1997,
22(5): 481-486.
[22] Kogan A, Direct solar thermal splitting of water and on-site separation of the products-II:
EXPerimental feasibility study [J], International Journal of Hydrogen Energy 1998, 23(2):
89-98.
[23] Baykara S.Z, EXPerimental solar water thermolysis [J], International Journal of
Hydrogen Energy, 2004, article in press.
[24] Harvey, S., Davidson, J.H., Fletcher, E.A, Thermolysis of hydrogen sulfide in the
temperature range 1350 to 1600K [J], Ind. Eng. Chem. Res 1998, 37: 2323-2332.
[25] Steinfeld A, Spiewak I, Economic evaluation of the solar thermal co-production of Zinc
and synthesis gas [J], Energy Conversion and Management 1998, 39(15): 1513-1518.
[26] Steinfeld A, Kuhn P, Reller A, Palumbo R, Murray J. Solar-processed metals as clean
energy carriers and water-splitters [J], International Journal of Hydrogen Energy 1998, 23(9):
767-774.
[27] Haueter P, Moeller S, Palumbo R, Steinfeld A, The production of Zinc by thermal
dissociation of Zinc oxide-solar chemical reactor design [J], Solar Energy 1999, 67(1-3):
161-167.
[28] Lede J, Elorza-Ricart E, Ferrer M, Solar thermal splitting of Zinc oxide: a review of
some of the rate controlling factors [J], Journal of Solar Energy Engineering 2001, 123(2):
91-97.
[29] Steinfeld A, Solar hydrogen production via a two-step water-splitting thermochemical
cycle based on Zn/ZnO redox reactions [J], International Journal of Hydrogen Energy 2002,
27(6): 611-619.
[30] Sakurai, M., Nakajima, H., Amir, R., Onuki, K., Shimizu, S, EXPerimental study on
side-reaction occurrence condition in the iodine-sulfur thermochemical hydrogen production
process [J], International Journal of Hydrogen Energy 2000, 25(7): 613-619.
[31] Sakurai, M., Gligen, E., Tsutsumi, A., Yoshida K, Solar UT-3 Thermochemical Cycle for
hydrogen production [J], Solar Energy 1996, 57(1): 51-58.
[32] http://www.pre.ethz.ch/cgi-bin/main.pl?research?project6
[33] http://solar.web.psi.ch/daten/projekt/elprod/elprod.html
[34] Babu BV, Chaurasia AS, Parametric Study of Thermal and Thermodynamic Properties on
Pyrolysis of Biomass in Thermally Thick Regime [J], Energy Conversion and Management
2004, 45: 53-72.
[35] Bridgwater AV, Peacocke GVC. Fast Pyrolysis Processes for biomass [J], Renewable and
Sustainable Energy Reviews 2000, 4(1):1-73.
[36] Williams.Paul T., Brindle. Alexander J. Catalytic Pyrolysis of Tyres: Influence of
Catalyst Temperature [J], Fuel 2002;81(18): 2425-2434.
[37] Chen G, Andries J, Spliethoff H. Catalytic Pyrolysis of Biomass for Hydrogen Rich Fuel
Gas Production [J], Energy Conversion and Management 2003; 44(14): 2289-2296.
[38] Sutton.D, Kelleher B, Ross JRH, Catalytic Conditioning of Organic Volatile Products
Produced by Peat Pyrolysis [J], Biomass and Bioenergy 2002; 23(3): 209-216.
[39]