Access provided by Autonomous University of Puebla. Download to read the full chapter text
Chapter PDF
Keywords
These keywords were added by machine and not by the authors. This process is experimental and the keywords may be updated as the learning algorithm improves.
References
Encyclopédie des gaz, Air Liquide, Division scientifique, Amsterdam, Elsevier (1976)
S. Satyapal, J. Petrovic, C. Read, G. Thomas, and G. Ordaz, “The U.S. department of energy’s national hydrogen storage project: Progress towards meeting hydrogen-powered vehicle requirements”, Catalysis Today 120 (2007) 246
P. Petit, “Séparation et liquéfaction des gaz”, Techniques de l’Ingénieur, traitéGénie des procédés, Volume J3 600
R. Drnevich, “Hydrogen delivery: liquefaction and compression”, Strategic initiatives for hydrogen delivery workshop, May 7 (2003)
http://www.hydropac.com/
http://www.pdcmachines.com/
bib07}P. Muthukumar, M.P. Maiya, and S.S. Murthy “Experiments on a metal hydride based hydrogen compressor”, International Journal of Hydrogen Energy, 30 (2005) 879
F. Laurencelle, Z. Dehouche, and J. Goyette, T.K. Bose “Integrated electrolyser-metal hydride compression”, International Journal of Hydrogen Energy, 31 (2006) 762
X. Wang, R. Chen, Y. Zhang, C. Chen, and Q. Wang “Hydrogen storage alloys for high-pressure suprapure hydrogen compressor”, Journal of Alloys and compounds, 420 (2006) 322
M. Au and Q. Wang “Rare earth-nickel alloy for hydrogen compression”, Journal of Alloys and compounds, 201 (1993) 115
Z. Dehouche, N. Grimard, F. Laurencelle, J. Goyette, and T.K. Bose, “Hydride alloys properties investigations for hydrogen sorption compressor”, Journal of Alloys and compounds, 399 (2005) 224
B. Rohland, K. Eberle, R. Ströbel, J. Scholta, and J. Garche, “Electrochemical hydrogen compressor”, Electrochimica Acta, 43(24)(1998) 3841
R. Ströbel, M. Oszcipok, M. Fasil, B. Rohland, L. Jörissen, and J. Garche, “The compression of hydrogen in an electrochemical cell based on a PE fuel cell design”, Journal of Power Sources, 105 (2002) 208
S. Porter, “Hydrogen generation from electrolysis”, Proton Energy Systems, May 23 (2005)
R. Maruyama, “Electrochemical hydrogen storage into LaNi5 using a fullerene-based proton conductor”, Electrochemical and Solid-State Letters, 5(5) (2002) A89
R.S. Irani, Material Research Society Bulletin (2002) 680
http://www.qtww.com/
G.E. McIntosh, “Hydrogen liquefiers since 1950”, Advances in Cryogenic Engineering: Transactions of the Cryogenic Engineering Conference – CEC, Volume 49 (2004) 9
J. Gallarda, “Liquéfaction de l’hydrogéne”, Techniques de l’Ingénieur, traitéGénie des procédés, J3, 603
M. Bracha, G. Lorenz, A. Patzelt, and M. Wanner, “Large-scale hydrogen liquefaction in Germany”, International Journal of Hydrogen Energy, 19(1) (1994) 53
J. Wolf, “Liquid – Hydrogen Technology for Vehicles”, Material Research Society Bulletin (2002) 684
G. Krainz, G. Bartlok, P. Bodner, P. Casapicola, Ch. Doeller, F. Hofmeister, E. Neubacher, and A. Zieger, “Development of Automotive Liquid Hydrogen Storage Systems”, Advances in Cryogenic Engineering:Transactions of the Cryogenic Engineering Conference – CEC, 49 (2004) 35
B. Kelly, “Liquefaction and pipeline costs”, Hydrogen Delivery Analysis Meeting, May 2007, Columbia, Maryland, USA
M.T. Syed, S.A. Sherif, T.N. Veziroglu, and J.W. Sheffield, “An economic analysis of three hydrogen liquefaction systems”, International Journal of Hydrogen Energy, 23(7) (1998) 565
H. Quack, “Conceptual design of a high efficiency large capacity hydrogen liquefier”, Advances in Cryogenic Engineering: Proceedings of the Cryogenic Engineering Conference, 47 (2002) 255
K. Ohira, K. Nakamichi, and H. Furumoto, “Experimental study on magnetic refrigeration for the liquefaction of hydrogen”, Advances in Cryogenic Engineering, 45 (2000) 1747
A.J. DeGregoria, L.J. Geuling, J.F. Laatsch, and J.R. Rowe, “Test results of an active magnetic regenerative refrigerator”, Advances in Cryogenic Engineering, 37, Part B (1992) 875
C.B. Zimm, E.M. Ludeman, M.C. Severson, and T.A. Henning, “Materials for regenerative magnetic cooling spanning 20 K to 80 K”, Advances in Cryogenic Engineering, 37, Part B (1992) 883
K.A. Gschneidner, Jr., H. Takeya, J.O. Moorman, V.K. Pecharsky, S.K. Malik, and C.B. Zimm “New magnetic refrigeration materials for the liquefaction of hydrogen”, Advances in Cryogenic Engineering, 39, Part B (1994) 1457
K.A. Gschneidner, Jr., V.K. Pecharsky, and S.K. Malik, “The (Dy1 - xErx)Al2 alloys as active magnetic regenerators for magnetic refrigeration”, Advances in Cryogenic Engineering, 42 (1996) 475
M.A. Richard, A.M. Rowe, and R. Chahine, “Magnetic refrigeration: Single and multimaterial active magnetic regenerator experiments”, Journal of Applied Physics, 95(4) (2004) 2146
A. Zuettel, P. Sudan, Ph. Mauron, T. Kiyobayashi, Ch. Emmenegger, and L. Schlapbach, “Hydrogen storage in carbon nanostructures”, International Journal of Hydrogen Energy, 27 (2002) 203
M.G. Nijkamp, J.E. Raaymakers, A.J. van Dillen, and K.P. deJong, “Hydrogen storage using physisorption-materials demand”, Applied Physics A, 72 (2001) 619
E. Poirier, R. Chahine, P. Bénard, D. Cossement, L. Lafi,E. Melançon, T.K. Bose, and S. Désilets, “Storage of hydrogen on single-walled carbon nanotubes and other carbon structures”, Applied Physics A, 78 (2004) 961
B. Panella and M. Hirscher, “Hydrogen adsorption in different carbon nanostructures”, Carbon, 43 (2005) 2209
M Hirscher and B. Panella “Large surface area nanostructures for hydrogen storage”, {Annales}de Chimie Science des Matériaux, 30(5) (2005) 519
M. Eddaoudi, J. Kim, N. Rosi, D. Vodak, J. Wachter, M. O’Keeffe, and O.M. Yaghi, “Systematic design of pore size and functionality in isoreticular MOFs and their application in methane storage”, Science, 295 (2002) 469
O.M. Yaghi, M. O’Keeffe, N.W. Ockwig, H.K. Chae, M. Eddaoudi, and J. Kim, “Reticular synthesis and the design of new materials”, Nature, 423 (2003) 705
J.L.C. Roswell, A.R. Milward, K.S. Park, and O.M. Yaghi, “Hydrogen sorption in functionalized metal-organic framework”, Journal of the American Chemical Society, 126 (2004) 5666
B. Panella and M. Hirscher, “Hydrogen physisorption in metal-organic porous crystals”, Advanced Materials, 17(5) (2005) 538
M Hirscher and B. Panella, “Hydrogen storage in metal-organic frameworks”, Scripta Materialia, 56 (2007) 809
N. Texier-Mandoki, J. Dentzer, T. Piquero, S. Saadallah, P. David, and C. Vix-Guterl, “{Hydrogen}storage in activated carbon materials: Role of nanoporous texture”, Carbon, 42 (2004) 2735
R. Gadiou, S. Saadallah, T. Piquero, P. David, J. Parmentier, and C. Vix-Guterl, “The influence of textural properties on the adsorption of hydrogen on ordered nanostructured carbons”, Microporous and Mesoporous Materials, 79 (2005) 121
A.G. Wong-Foy, A.J. Matzer, and O.M. Yaghi, “Exceptional H2 saturation uptake in microporous metal-organic frameworks”, Journal of the American Chemical Society 128 (2006) 3494
D.J. Collins and H.-C. Zhou, “Hydrogen storage in metal-organic frameworks”, Journal of Material Chemistry, 17 (2007) 3154
T. Yildirim and M.R. Hartman, “Direct observation of hydrogen adsorption sites and nanocage formation in metal-organic frameworks”, Physical Review Letters, 95 (2005) 215504
J.L.C. Roswell, J. Eckert, and O.M. Yaghi, “Characterization of H2 binding sites in prototypical metal-organic frameworks by inelasticneutron scattering”, Journal of American Chemical Society, 127 (2005)
G. Sandrock and G. Thomas, “The IEA/DOE/SNL on-line hydride databases”, Applied Physics A, 72(2) (2001) 153
J.H.N. Van Vucht, F.A. Kuijpers, and H.C.A.M. Bruning, Philips Research Report, 25 (1970) 133
R. Cerny, J.M. Joubert, M. Latroche, A. Percheron-Guégan, and K. Yvon, Journal of Applied Crystallography, 33 (2000) 997
C. Lartigue, A. Percheron-Guégan, J.C. Achard, and F. Tasset, Journal of the Less Common Metals, 75 (1980) 23
G. Sandrock, “Hydrogen-metal systems” in Hydrogen Energy System, Y. Yürüm (ed.), Kluwer Academic Publishers, Netherlands (1995) 135
F. Cuevas, J.M. Joubert, M. Latroche, and A. Percheron-Guégan, “Intermetallic compounds as negative electrodes of Ni/MH batteries”, Applied Physics A, 72 (2001) 225
J.M. Joubert, M. Latroche, and A. Percheron-Guégan, “Metallic hydrides II: Materials for electrochemical storage”, Material Research Society Bulletin September (2002) 694
G. Liang, “Synthesis and hydrogen storage properties of Mg-based alloys”, Journal of Alloys and Compounds, 370 (2004) 123
J.J. Reilly, “Synthesis and properties of useful metal hydrides”, in Hydrides for energy storage, A.F. Andresen and A.J. Maeland (eds), Pergamon press, Oxford (1978) 301
A. Zaluska, L. Zaluski, and J.O. Ström-Olsen, “Nanocrystalline magnesium for hydrogen storage”, Journal of Alloys and Compounds, 288 (1999) 217
Y. Chen and J.S. William, “Formation of metal hydrides by mechanical alloying” Journal of Alloys and Compounds, 217 (1995) 181
H. Imamura, M. Kawahigashi, and S. Tsuchiya “Exceptionally active magnesium for hydrogen storage: Solvated magnesium clusters formed in low temperature matrices”, Journal of the Less Common Metals, 95 (1983) 157
B. Bogdanovic, “Magnesium hydride: A homogeneous-catalysed synthesis and its use in hydrogen storage”, International Journal of Hydrogen Energy, 9 (1984) 937
A. Altmann and T. Schober, “Hydrides in Mg and Ti produced by hydrogen ion implantation”, Scripta Metallurgica and Materialia, 25(3) (1991) 723
A.S. Pedersen, “Magnesium (Beryllium) and alkaline earth (calcium, strontium and barium) hydrides”, in Solid State Phenomena, E.A. Lewis and A. Aladjem (eds), Scitec Publications volume 49–50 (1996) 46
H. Ellinger, C.E. Holley, B.B. McInteer, D. Pavone, R.M. Potter, E. Staritsky, and W.H. Zachariasen, “The preparation and some properties of magnesium hydride”, Journal of American Chemical Society, 77 (1955) 2647
W.H. Zachariasen, CE. Holley, and J.F. Stamper, “Neutron diffraction study of magnesium hydride”, Acta Crystallographica, 16 (1963) 352
A. San-Martin and F.D. Manchester, “The H-Mg (Hydrogen-Magnesium) system”, Bulletin of Alloy Phase diagrams, 8(5) (1987) 431
J.F. Stamper, Jr., C.E. Holley, Jr., and J.F. Suttle, “The magnesium-hydrogen system”, Journal of American Chemical Society, 82 (1960) 3504–3508
B. Tanguy, J.L. Soubeyroux, M. Pezat, J. Portier, and P. Hagenmuller, “Amélioration des conditions de synthése de l’hydrure de magnésium àl’aide d’adjuvants”, Material Research Bulletin, 11, (1976) 1441–1448
A.S. Pedersen, J. Kjøller, B. Larsen, B. Vigeholm, and J.A. Jensen, “Magnesium for hydrogen storage”, International Journal of Hydrogen Energy, 8 (1983) 205–211
L. Belkbir, E. Joly, and N. Gerard, “Comparative study of the formation-decomposition mechanisms and kinetic in LaNi5 and magnesium reversible hydride”, International Journal of Hydrogen Energy, 6 (1981) 2145–2156
B. Bogdanovic, A. Ritter, B. Spliethoff, and K. Straßburger, “A process steam generator based on the high temperature magnesium hydride/magnesium heat storage system”, International Journal of Hydrogen Energy, 20 (1995) 811–822.
G. Friedlmeier and M. Groll, “Experimental analysis and modelling of the hydriding kinetics of Ni-doped and pure Mg”, Journal of Alloys and compounds, 253–254 (1997) 550–555,
B. Bogdanovic, K. Bohmhammel, B. Christ, A. Reiser, K. Schlichte, R. Vehlen, and U. Wolf, “Thermodynamic investigation of the magnesium-hydrogen system”, Journal of Alloys and compounds, 282 (1999) 84–92
B. Vigeholm, J. Kjøller, and B. Larsen, “Magnesium for hydrogen storage”, Journal of the Less Common Metals, 74 (1980) 341–350
B. Vigeholm, “Magnesium as an energy material”, Proceedings – World Magnesium Conference, Proceedings – 41st World Magnesium Conference, London, pp. 59–63
A. Zaluska, L. Zaluski, and J.O. Ström-Olsen, “Nanocrystalline magnesium for hydrogen storage”, Journal of Alloys and Compounds, 288 (1999) 217–225
A.S. Pedersen, J. Kjøller, B. Larsen, and B. Vigeholm, “On the hydrogenation mechanism in magnesium I”, in Hydrogen energy progress V,Proceedings of the 5th World Hydrogen Energy Conference, Toronto 15–20 July 1984, ed. by T.N. Veziroglu and J.B. Taylor, Pergamon Press, New-York, pp. 1269–1277
C.P. Chen, B.H. Liu, Z.P. Li, and J. Wu, “The activation mechanism of Mg-based hydrogen storage alloys”, Zeitschrift fur Physikalisch Chemie B, 181 (1993) 259–267
E. Ivanov, I. Konstanchuk, A. Stepanov, and V. Boldyrev “Magnesium mechanical alloys for hydrogen storage”, Journal of the Less Common Metals, 131 (1987) 25–29
S. Bouaricha, J.P. Dodelet, D. Guay, J. Huot, S. Boily, and R. Schulz, “Hydriding behavior of Mg-Al and leached Mg-Al compounds prepared by high-energy ball milling”, Journal of Alloys and Compounds. 297 (2000) 282–293
H. Imamura, S. Tabata, Y. Takesue, Y. Sakata, and S. Kamazaki, “Hydriding-dehydriding behavior of magnesium composites obtained by mechanical grinding with graphite carbon”, International Journal of Hydrogen Energy, 25 (2000) 837–843
M. Khrussanova, J.-L. Bobet, M. Terzieva, B. Chevalier, D. Radev, P. Peshev, and B. Darriet, “Hydrogen storage characteristics of magnesium mechanically alloyed with YNi5 - xAlx (x=0, 1 and 3)”, Journal of Alloys and Compounds, 307 (2000) 283–289
P. Wang, A.M. Wang, H.F. Zhang, B.Z. Ding, and Z.Q. Hu, “Hydrogenation characteristics of Mg-TiO2 (rutile) composite”, Journal of Alloys and Compounds, 313, (2000) 218–223
M. Terzieva, M. Khrussanova, and P. Peshev, “Hydriding and dehydriding characteristics of Mg-LaNi5 composite materials prepared by mechanical alloying”, Journal of Alloys and Compounds, 267 (1998) 235–239
G. Liang, S. Boily, J. Huot, A. Van Neste, and R. Schulz, “Hydrogen absorption properties of a mechanically milled Mg-50 wt.% LaNi5 composite”, Journal of Alloys and Compounds, 268, (1998) 302–307
P. Selvam, B. Viswanathan, C.S. Swamy, and V. Srinivasan, “Magnesium and magnesium alloy hydrides”, International Journal of Hydrogen Energy, 11(3) (1986) 169–192
M. Khrussanova, “Metal alloy hydrides for hydrogen storage”, Bulgarian Academy of Science, 19(3), (1986) 358–373
S. Orimo and H. Fujii, “Materials science of Mg-Ni-based new hydrides”, Applied Physics A, 72(2) (2001) 167–186
G. Liang, J. Huot, S. Boily, A. Van Neste, and R. Schulz, “Hydrogen storage properties of the mechanically milled MgH2-V nanocomposite”, Journal of Alloys and Compounds, 291, (1999) 295–299
W. Oelerich, T. Klassen, and R. Bormann, “Metal oxides as catalysts for improved hydrogen sorption in nanocrystalline Mg-based materials”, Journal of Alloys and Compounds, 315 (2001) 237–242
G. Liang, J. Huot, S. Boily, and R. Schulz, “Hydrogen desorption kinetics of a mechanically milled MgH2 + 5 at.% V nanocomposite”, Journal of Alloys and Compounds, 305 (2000) 239.
J.F. Pelletier, J. Huot, M. Sutton, R. Schulz, A.R. Sandy, L.B. Lurio, and S.G.J. Mochrie, “Hydrogen desorption mechanism in MgH2 – Nb nanocomposite”, Physical review B, 63 (2000) 521
G. Barkhordarian, T. Klassen, and R. Bormann, Scripta Materialia, 49 (2003) 213
N. Hanada, T. Ichikawa, S. Hino, and H. Fujii, “Remarkable improvement of hydrogen sorption kinetics in magnesium catalyzed with Nb2O5”, Journal of Alloys and Compounds, 420 (2000), 46–49
M. Dornheim, N. Eigen, G. Barkhordarian, T. Klassen, and R. Bormann, Advanced Engineering Materials, 8(5) (2006) 377–385
S.I. Orimo, Y. Nakamori, J.R. Eliseo, A. Züttel, and C.M. Jensen, “Complex Hydrides for Hydrogen Storage”, Chemical Reviews, 107 (2007) 4111–4132
J. Chen, N. Kuriyama, Q. Xu, H.T. Takeshita, and T. Sakai, “Reversible hydrogen storage via titanium-catalyzed LiAlH4 and Li3AlH6”, Journal of Physical Chemistry B, 105 (2001) 11214–11220
H. Morioka, K. Kakizaki, S.-C. Chung, and A. Yamada, “Reversible hydrogen decomposition of KAlH4”, Journal of Alloys and Compounds, 353 (2003) 310–314
M. Fichtner, O. Fuhr, and O, Kircher, “Magnesium alanate – a material for reversible hydrogen storage?”, Journal of Alloys and Compounds, 356–357 (2003) 418–422
M. Mamatha, B. Bogdanovic, M. Felderhoff, A. Pommerin, W. Schmidt, F. Schüth, and C. Weidenthaler, “Mechanochemical preparation and investigation of properties of magnesium, calcium and lithium-magnesium alanates”, Journal of Alloys and Compounds, 407 (2006) 78–86
http://www.albemarle.com/Products_and_services/Fine_chemicals/
P. Claudy et al., “Etude du comportement thermique du tetrahydroaluminate de sodium NaAlH4 et de l’hexahydroaluminate de sodium Na3AlH6 de 298 a 600 K”, Thermochimica Acta, 8 (1980) 75
B. Bogdanovic and M. Schwickardi, “Ti-doped alkali metal aluminium hydrides as potential novel reversible hydrogen storage materials”, Journal of Alloys and Compounds, 253–254, (1997) 1–9
B.C. Hauback, H.W. Brinks, C.M. Jensen, K. Murphy, and A.J. Maeland, “Neutron diffraction structure determination of NaAlD4”, Journal of Alloys and Compounds, 358 (2003) 142–145
D.L. Anton, “Hydrogen desorption kinetics in transition metal modified NaAlH4”, J. Alloys and Compounds, 356 (2003) 400
B. Bogdanovic, G. Sandrock, “Catalized complex Metal Hydrides”, MRS bulletin, 712 (2002)
M. Fichtner, O. Fuhr, O. Kircher, and J. Rothe, “Small Ti clusters for catalysis of hydrogen exchange in NaAlH4”, Nanotechnology, 14 (2003) 778
B. Bogdanovic, M. Felderhoff, S. Kaskel, A. Pommerin, K. Schlichte, and F. Schüth, “Improved hydrogen storage properties of Ti-doped sodium alanate using titanium nanoparticles as doping agents”, Advanced Materials, 15 (2003) 1012
B. Bogdanovic, M. Felderhoff, A. Pommerin, F. Schüth, and N. Spielkamp, “Advanced hydrogen storage materials based on Sc-, Ce-, and Pd-doped NaAlH4”, Advanced Materials, 18 (2006) 1198
O. Kircher and M. Fichtner, “Hydrogen exchange kinetics in NaAlH4 catalyzed in different decomposition states”, Journal of Applied Physics, 95(12) (2004) 7748
A. Léon, O. Kircher, J. Rothe, and M. Fichtner, “Chemical state and local structure around titanium atoms in NaAlH4 doped with TiCl3 using X-ray absorption spectroscopy”, The Journal of Physical Chemistry B, 108 (2004) 16372
J. Graetz, J.J. Reilly, J. Johnson, A.Y. Ignatov, and T.A. Tyson, “X-ray absorption study of Ti-activated sodium aluminum hydride”, Applied Physics Letters, 85 (2004) 500
M. Felderhoff, K. Klementiev, W. Grünert, B. Spielthoff, B. Tesche, J.M. Bellosta von Colbe, B. Bogdanovic, M. Härtel, A. Pommerin, F. Schüth, and C. Weidenthaler, “Combined TEM-EDX and XAFS studies of Ti-doped sodium alanate”, Physical Chemistry Chemical Physica, 6 (2004) 4369
A. Léon, O. Kircher, J. Röthe, S. Dieter, and M. Fichtner, “Evolution of the local structure around Ti atoms in NaAlH4 doped with TiCl3 or small Ti clusters (Ti13 .6THF) by ball milling”, Journal of Physical Chemistry B, 110 (2006) 1192
P. Canton, M. Fichtner, C. Frommen, and A. Léon “Synchrotron X-ray studies of Ti-doped NaAlH4”, Journal of Physical Chemistry B, 110 (2006) 3051
S. Singh, S.W.H. Eijt, J. Huot, W.A. Kockelmann, M. Wagemaker, and F.M. Mulder, “The TiCl3 catalyst in NaAlH4 for hydrogen storage induces grain refinement and impacts on hydrogen vacancy formation”, Acta Materialia 55 (2007) 5549
P. Chen, Z. Xiong, J. Luo, J. Lin, and K.L. Tan, “Interaction of hydrogen with metal nitrides and imides”, Nature, 420 (2002) 302–304
P. Chen, Z. Xiong, G. Wu, Y. Liu, J. Hu, and W. Luo, Scripta Materialia, 56 (2007) 817
H. Fujii and T. Ichikawa, “Recent development on hydrogen storage materials composed of light elements”, Physica B, 383 (2006) 45–48
W. Luo, “(LiNH2 – MgH2): A viable hydrogen storage system”, Journal of Alloys and Compounds, 381 (2004) 284–287
G.L. Soloveichik, “Metal borohydrides as hydrogen storage materials”, Materials Matters, 2 (2007) 11–14
J.J. Vajo, S.L. Skeith, and F. Martens, “Reversible storage of hydrogen in destabilized LiBH4”, Journal of Physical chemistry B, 109 (2005) 3719–3722
J.J. Vajo and G.I. Olson, “Hydrogen storage in destabilized chemical systems”, Scripta Materialia, 56 (2007) 829
G. Barkhordarian, T. Klassen, M. Dornheim, and R. Bormann, “Unexpected kinetic effect of MgB2 in reactive hydride composites containing complex borohydrides”, Journal of Alloys and Compounds, 440 (2007) L18–L21
J. Huot, G. Liang, and R. Schulz, “Magnesium-based nanocomposites chemical hydrides”, Journal of Alloys and Compounds, 353 (2003) L12
S.C. Amendola, “Process for synthesizing borohydride compounds”, US patent 6524542 (2003)
http://www.millenniumcell.com
P. Ferreira-Aparacio, I. Rodriguez-Ramos, and A. Guerrero-Ruiz, “Pure hydrogen production from methylcyclohexane using a new high performance membrane reactor”, Chemical Communications 2002(18) (2002) 2082
G. Bustamante, Y. Swesi, I. Pitault, V. Meille, and F. Heurtaux, “A hydrogen storage an transport mean”, Proceedings International Energy Congress and Exhibition IHEC (2005) Turkey
http://www.airproducts.com
A. Cooper and G. Pez, “Development of new carbon-based sorbent systems for an effective containment of hydrogen”, DOE Annual Merit Review Presentation (2005), available at: http://www.hydrogen.energy.gov/annual_progress05_storage.html
http://wwww.asemblon.com
E.D. Naeemi, D. Graham, and B.F. Norton, “Introducing HYDRNOL TM: Organic liquid storage for hydrogen”, Sigma Aldrich, 2(2) (2007) 23
Author information
Authors and Affiliations
Editor information
Editors and Affiliations
Rights and permissions
Copyright information
© 2008 Springer-Verlag Berlin Heidelberg
About this chapter
Cite this chapter
Léon, A. (2008). Hydrogen Storage. In: Léon, A. (eds) Hydrogen Technology. Green Energy and Technology. Springer, Berlin, Heidelberg. https://doi.org/10.1007/978-3-540-69925-5_3
Download citation
DOI: https://doi.org/10.1007/978-3-540-69925-5_3
Publisher Name: Springer, Berlin, Heidelberg
Print ISBN: 978-3-540-79027-3
Online ISBN: 978-3-540-69925-5
eBook Packages: EngineeringEngineering (R0)